Team:Harvard/Daily
From 2009.igem.org
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Reactions were run according to the following | Reactions were run according to the following | ||
+ | Dilution, PCR, gel, gel extraction, digest, PCR cleanup, ligation, transformation | ||
+ | Gel, gel extract, digest, PCR cleanup, and then ready for ligations tomorrow. | ||
+ | Transformation | ||
+ | |||
+ | PCR Reactions for amplification of PIF3 and PhyB from plasmids from Florida. | ||
+ | 5 ul 10x buffer | ||
+ | 1 ul DNTPs | ||
+ | 1 ul fwd primer (at 10 uM) | ||
+ | 1 ul reverse primer (at 10 uM) | ||
+ | 1 ul DNA (rxns 1, 3, 5 stock, 2, 4, 6, 10 fold dilution from stock) | ||
+ | 1 uL VENT enzyme | ||
+ | 40 uL ddH20 | ||
+ | 50 ul total volume | ||
Line 437: | Line 450: | ||
</p> | </p> | ||
<h3> Week 4: 6/29/09 - 7/3/09 </h3> | <h3> Week 4: 6/29/09 - 7/3/09 </h3> | ||
- | <p> | + | <p> pGal promoter with luciferase (either red or green)—For the two hybrid system |
+ | Into 17 and 18 plasmids from Murray lab (pFA6a + Gal1). Digest plasmids with BamHI and SalI (Buffer 3 BSA 37), and then ligate in the luciferase fragment, PCRed out with the following primers. Sites selected because absent in luciferase and easy to use in the Gal1 plasmids. | ||
+ | F.luciferase.BamHI AAGCTTGGT TCCAAA atggaagacgccaaaaacataaag Tm65 | ||
+ | R.luciferase.SalI AAG CTT GTC GAC AAA ttactttccgcccttcttggcc Tm 71 | ||
+ | |||
+ | Plasmid 1-BamHI/SalI works | ||
+ | Plasmid 2-SpeI/HindIII | ||
+ | Plasmid 3-BamHI/SalI works | ||
+ | |||
+ | For pPS293 Vector | ||
+ | F.luciferase.SpeI AAGCTT ACT AGT AAA atggaagacgccaaaaacataaag | ||
+ | R.luciferase.HindIII AAG CTT AAG CTT AAA ttactttccgcccttcttggcc | ||
+ | |||
+ | For the pET-GFP-POS36 (David’s plasmid) | ||
+ | F.Luciferase.NcoI AAGCTT CC A TGG aagacgccaaaaacataaag | ||
+ | R.Luciferase.XhoI AAG CTT CTC GAG ttattactttccgcccttcttggcc | ||
+ | |||
+ | For one of the random plasmids from Pam Silver’s lab. Except then we decided not to do this. | ||
+ | F.luciferase.BamHI AAGCTTGGT TCCAAA atggaagacgccaaaaacataaag Tm65 | ||
+ | R.luciferase.HindIII AAG CTT AAG CTT AAA ttactttccgcccttcttggcc | ||
+ | |||
+ | PCR | ||
+ | Reactions | ||
+ | Red Green | ||
+ | 5 ul Thermopol Buffer 5 ul Thermopol Buffer | ||
+ | 1 ul dNTPs 1 ul dNTPs | ||
+ | 1 ul F.luciferase.BamHI 1 ul F.luciferase.BamHI | ||
+ | 1 ul R.luciferase.SalI 1 ul R.luciferase.SalI | ||
+ | 1 ul Red DNA 1 ul Green DNA | ||
+ | 1 uL VENT 1 ul VENT | ||
+ | 40 uL H20 40 uL H20 | ||
+ | |||
+ | Thermocycler conditions | ||
+ | 5 minutes melting at 95 | ||
+ | Per cycle: 30 seconds melting at 95 | ||
+ | 5 cycles at annealing temp 47, 30 cycles at annealing temp 52 | ||
+ | Extension 1 min 48 sec at 72 degrees | ||
+ | 5 minutes at 72 degrees | ||
+ | |||
+ | Gel. Lane 2 Red, Lane 3 green. Both show fragments of approx 1650 bp, which is as expected for full length luciferase! This means we have successful amplification of the desired fragments with the appropriate restriction sites for insertion into the 17 pFA6a-TRP1-pGAL1 and 18 pFA6a-HIS3-pGAL1 plasmids from the Murray lab. Those restriction sites are the ones present downstream of the promoter in the MCS so ligation should work well! | ||
+ | |||
+ | |||
+ | Purification. PCR reactions were purified via column purification and eluted in 50 uL of water. Resulted in the following concentrations: Red- 398 ng/ul, green- 42 ng/ul, 17-154 ng/ul, 18-238 ng/ul. | ||
+ | |||
+ | Digests. Fragments and vectors were digested to create complementary sticky ends for ligation. Ligations were run at 37 degrees for an hour and a half. | ||
+ | Red Green 17 pFA6a-TRP 18 pFA6a-HIS | ||
+ | 1 ul BamHI 1 ul BamHI 1 ul BamHI 1 ul BamHI | ||
+ | 1 ul SalI 1 ul SalI 1 ul SalI 1 ul SalI | ||
+ | 1 ul Dpn1 1 ul Dpn1 | ||
+ | 6.5 uL Buffer 3 6.5 uL Buffer 3 3 uL Buffer 3 3 uL Buffer 3 | ||
+ | 6.5 uL BSA 6.5 uL BSA 3 uL BSA 3 uL BSA | ||
+ | 50 uL DNA 50 uL DNA 10 uL DNA 10 uL DNA | ||
+ | |||
+ | Purification. Column purification of the digest fragments resulted in the following concentrations: Red-34.8 ng/ul, Green-35.1 ng.ul, 17- 31.6 ng/ul, and 18-54.9 ng/ul | ||
+ | |||
+ | Ligations. Fragments from the above digests were ligated to create the complete reporter for the yeast two hybrid system. Ligations were done on 50 uL | ||
+ | (A) Red+17 (B) Red+18 (C) Green+17 (D) Green+18 Control Red Control 17 | ||
+ | 1.5 uL Red 1.5 uL Red 1.5 uL green 1.5 uL green 1.5 uL Red | ||
+ | 1.6 uL 17 1.0 uL 18 1.6 uL 17 1.0 uL 18 1.6 uL 17 | ||
+ | 2 uL T4 buffer 2 uL T4 buffer 2 uL T4 buffer 2 uL T4 buffer 2 uL T4 buffer 2 uL T4 buffer | ||
+ | 1 ul QuikLigase 1 ul QuikLigase 1 ul QuikLigase 1 ul QuikLigase 1 ul QuikLigase 1 ul QuikLigase | ||
+ | 15 uL water 15 uL water 15 uL water 15 uL water 15 uL water 15 uL water | ||
+ | |||
+ | Transformation. 5 uL of ligation was transformed into TOP10 cells and allowed to grow for an hour following standard protocol. These were then plated onto amp plates, and grown overnight. A control of 17 digested backbone alone and red fragment alone was also carried out, which resulted in many colonies on the backbone control plate, far more than on the ligation plates. But colony PCR revealed these fewer colonies on the ligation plates to be correct. Oliver thought the strangeness with the control was due to incomplete cutting of the vector and efficient recircularization in the absence of insert, but that it was less efficient when the insert was present. | ||
+ | |||
+ | Colony PCR. Colony PCR was carried out to determine if vectors 17 and 18 ligated to the red and green luciferases actually contain the inserts. | ||
+ | Rxn Mix for 20 reactions: | ||
+ | 20 uL 10x –MG buffer | ||
+ | 4 uL 10 nM dNTP mix | ||
+ | 6 uL 50 nM MgCl2 | ||
+ | 5 uL Primer Fwd F.luciferase.BamHI | ||
+ | 5 uL Primer Rev R.luciferase.SalI | ||
+ | 10 uL Taq | ||
+ | 150 uL Water | ||
+ | |||
+ | 10 uL aliquots were made, and ½ a culture added to each one, 5 from each of the 4 plates for a total of 20 colony PCRs. Thermocycler conditions were annealing 52 for 5 cycles then 55 for 25 cycles, extension time of 1 min 48 seconds because expected length of fragment is 1.65 kB (and I rounded up a little bit). | ||
+ | |||
+ | Gels of Colony PCR products | ||
+ | Gel 1. Lanes 2-6 are A1-A5, lanes 7-11 are B1-B5 | ||
+ | Gel2. Lanes 2-6 are C1-C5, lanes 7-11 are D1-D5 | ||
+ | |||
+ | |||
+ | Colony Picking. Amy picked colonies to grow up for large scale prepping (this is an integrating vector and requires up to 10 ug per yeast transfection, but this will then create a stable line. But we need enough). Colonies picked were: A1, B3, C4, D5. Cultures grown with Amp, uL/mL, 100 mL cultures. Unfortunately nothing grew, we are repacking and culturing again tonight in the hopes that it was just because we left them on the counter for too long before putting them into the shaker. It was not likely that it was due to the Amp, because we used two different aliquots between the 4 cultures but none of the 4 grew. | ||
+ | </p> | ||
<h3> Week 5: 7/6/09 - 7/10/09 </h3> | <h3> Week 5: 7/6/09 - 7/10/09 </h3> | ||
- | <p> | + | <p> Split Luciferase System Cloning |
+ | |||
+ | Primer Design for Split Luciferase | ||
+ | 1. pFA6a primers (Nhe + SexAI) | ||
+ | a. pFA6a forward (after citrine)— SexAI site+ sequence | ||
+ | 5’-Filler + SexAI + Filler + plasmid sequence-3’ | ||
+ | F. pFA6a.plasmid.SpL.SexAI AAG CTT ACC AGG TAA AAA ggcgcgccacttctaaataagc-3’ (41) --overlap Tm57 total 67 | ||
+ | F. pFA6a.SpL.SexAI.new TTA CCA GGT AAggcgcgccacttctaaataagc overlap 57, total 65 | ||
+ | b. pFA6a reverse (before citrine)—NheI site + sequence from start of citrine rev comp | ||
+ | R.pFA6a.plasmid.SpL.Nhe AAG CTT GCT AGC AAA tgttaattcagtaaattttcgatc 3’ (39) – Tm55 or 47. THIS PRIMER IS THE PROBLEM! TOTALLY. | ||
+ | R.pFA6a.SpL.Nhe.new CTT GCT AGC gttaattcagtaaattttcgatcttgggaag overlap 56 total 63 | ||
+ | 2. Nfluc (1-398) primers (Nhe + Kpn) | ||
+ | a. nFluc forward—NheI site + sequence | ||
+ | F.Nfluc.SpL.NheI AAG CTT GCT AGC AAA atggaagacgccaaaaacataaag (39)—Tm52 | ||
+ | b. nFluc reverse—KpnI site | ||
+ | R.Nfluc.SpL.KpnI AAG CTT GGT ACC AAA cataatcataggtcctctgacac (38)—Tm 53 | ||
+ | |||
+ | 3. Cfluc (349-548) (Kpn + SexAI) | ||
+ | a. cFluc forward—KpnI site | ||
+ | F.cFluc.SpL.KpnI AAG CTT GGT ACC AAA ggacctatgattatgtccggttatg (40)—Tm 56 | ||
+ | b. cFluc reverse—incl Stop codon, SexAI (also removed last three amino acids) | ||
+ | c. R.Cfluc.SpL.SexAI AAG CTT ACC AGG TAA AAA ttactttccgcccttcttggcc (40)—Tm 55 | ||
+ | |||
+ | 4. PhyB (1-621) (Kpn + SexAI) | ||
+ | a. PhyB forward—Kpn1 site | ||
+ | b. F.PhyB.SpL.KpnI AAG CTT GGT ACC AAA atggtttccggagtcggggg (35)—Tm 58 | ||
+ | c. PhyB reverse—Phy B, stop codon, SexAI, | ||
+ | R.PhyB.SpL.SexAI AAG CTT ACC AGG TAA AAA ttaaagctggagcgagtgaatc (40)—Tm 51 or 47 | ||
+ | |||
+ | R.PhyB.SpL.SexAI.correct AAG CTT ACC AGG TAA TTAAAGCTGGAGCGAGTGAATCGC 52/57 | ||
+ | R.PhyB.pST39.BclI.correct AAG CTT TGA TCA TTAAAGCTGGAGCGAGTGAATCGC 52/57 | ||
+ | |||
+ | 5. PIF3 full (Nhe + Kpn1)l | ||
+ | a. PIF3 full forward—NheI site | ||
+ | F.PIF3.SpL.NheI AAG CTT GCT AGC AAA atgcctctgtttgagcttttc (36)—Tm 50 or 57 | ||
+ | b. PIF3 full reverse—Kpn1 site (remove stop codon!) | ||
+ | R.PIF3.Full.SpL.KpnI AAG CTT GGT ACC AAA cgacgatccacaaaactgatc (36)—Tm 52 | ||
+ | 6. PIF 3 partial (Nhe + Kpn) | ||
+ | a. PIF3 partial reverse—Kpn1 site | ||
+ | R.PIF3.partial.SpL.KpnI AAG CTT GGT ACC AAA atgatgattcaaccatggaac (36)—Tm 49 or 55 | ||
+ | |||
+ | Xma/Nhe digest for insert—Buffer 4 (PhyB nterm) | ||
+ | Xma— CCC GGG | ||
+ | Nhe—GCT AGC | ||
+ | F.Nfluc.SpL.XmaI AAG CTT CCC GGG AAA atggaagacgccaaaaacataaag | ||
+ | R.PhyB.SpL.NheI AAG CTT GCT AGC TTA TTAAAGCTGGAGCGAGTGAATCGC | ||
+ | |||
+ | XmaI/EcoRI-HF digest for insert and for vector—Buffer 4. | ||
+ | Xma—CCC GGG | ||
+ | EcoRI—GAA TTC | ||
+ | |||
+ | F.PIF3.SpL.XmaI AAG CTT CCC GGG AAA atgcctctgtttgagcttttc | ||
+ | R.Cfluc.SpL.EcoRI AAG CTT GAATTC TTA ttactttccgcccttcttggcc | ||
+ | |||
+ | Checking frame for Nfluc+PhyB: agtgtcagaggacctatgattatgTTTGGTACCAAAatggtttccggagtcggggg. In frame! | ||
+ | Checking frame for PIF3+Cfluc: gatcagttttgtggatcgtcgTTTGGTACCAAAggacctatgattatgtccggttatg | ||
+ | |||
+ | F.PIF3.pST39.XmaI TAG CTT CCC GGG AAA atgcctctgtttgagcttttc 54, 67 | ||
+ | F.PIF3.SpL.NheI AAG CTT GCT AGC AAA atgcctctgtttgagcttttc 54, 65 | ||
+ | R.PIF3.Full.SpL.KpnI AAG CTT GGT ACC AAA cgacgatccacaaaactgatc 54, 65 | ||
+ | R.PIF3.partial.SpL.KpnI AAG CTT GGT ACC AAA atgatgattcaaccatggaac 51, 53 | ||
+ | 49, 55 | ||
+ | |||
+ | R.cFluc.pST39.MluI TAG CTT ACG CGT AAA ttactttccgcccttcttggcc 60, 67 | ||
+ | R.Cfluc.SpL.SexAI AAG CTT ACC AGG TAA AAA ttactttccgcccttcttggcc 60, 67 | ||
+ | F.cFluc.SpL.KpnI AAG CTT GGT ACC AAA ggacctatgattatgtccggttatg 55, 65 | ||
+ | 52, 57 | ||
+ | |||
+ | |||
+ | F.PIF3.pST39.XmaI TAG CTT CCC GGG AAA atgcctctgtttgagcttttc 54, 67 | ||
+ | R.cFluc.pST39.MluI TAG CTT ACG CGT AAA ttactttccgcccttcttggcc 60, 67 | ||
+ | |||
+ | F.PIF3.SpL.NheI AAG CTT GCT AGC AAA atgcctctgtttgagcttttc 54, 65 | ||
+ | R.Cfluc.SpL.SexAI AAG CTT ACC AGG TAA AAA ttactttccgcccttcttggcc 60, 67 | ||
+ | |||
+ | |||
+ | Split Luciferase PCR Reactions | ||
+ | No. Product Frag. DNA Forward Reverse Digest Buffer Expected Size | ||
+ | 1 His- vector pFA6a-Act-His F. pFA6a.plasmid.SpL.SexAI R.pFA6a.plasmid.SpL.Nhe SexAI/NheI/DpnI Buffer 4 + BSA @ 37, 1hr 5 kb | ||
+ | 2 Ura- vector pFA6a-Act-Ura F. pFA6a.plasmid.SpL.SexAI R.pFA6a.plasmid.SpL.Nhe SexAI/NheI/DpnI Buffer 4 + BSA @ 37, 1hr 5 kb | ||
+ | 3 Red Nfluc Red luciferase F.Nfluc.SpL.NheI R.Nfluc.SpL.KpnI NheI/KpnI/DpnI Buffer 1 + BSA @ 37, 1hr 1.2 kb | ||
+ | 4 Green Nfluc Green luciferase F.Nfluc.SpL.NheI R.Nfluc.SpL.KpnI NheI/KpnI/DpnI Buffer 1 + BSA @ 37, 1hr 1.2 kb | ||
+ | 5 R/G Cfluc Red luciferase F.cFluc.SpL.KpnI R.Cfluc.SpL.SexAI KpnI/SexAI/DpnI Buffer 1 + BSA @ 37, 1hr 450 bp | ||
+ | 6 PhyB Nterm PhyB florida F.PhyB.SpL.KpnI R.PhyB.SpL.SexAI KpnI/SexAI/DpnI Buffer 1 + BSA @ 37, 1hr 1.8 kb | ||
+ | 7 PIF3 Full PIF3 florida F.PIF3.SpL.NheI R.PIF3.Full.SpL.KpnI NheI/Kpn1/DpnI Buffer 1 + BSA @ 37, 1hr 1.6 kb | ||
+ | 8 PIF3 Partial PIF3 florida F.PIF3.SpL.NheI R.PIF3.partial.SpL.KpnI NheI/Kpn1/DpnI Buffer 1 + BSA @ 37, 1hr 300 bp | ||
+ | |||
+ | |||
+ | |||
+ | Construction Goals | ||
+ | HisVector/NheI/Nfluc Red/KpnI/PhyB/SexAI/Vector | ||
+ | HisVector/NheI/Nfluc Green/KpnI/PhyB/SexAI/Vector | ||
+ | UraVector/NheI/PIF3 full/KpnI/cFfluc/SexAI/Vector | ||
+ | UraVector/NheI/PIF3 partial/KpnI/cFfluc/SexAI/Vector | ||
+ | |||
+ | His Vector+ Nfluc-PhyB | ||
+ | 1. PCR Reactions | ||
+ | a. In order to obtain vector backbone without the inserted citrine, PCR around the pFA6a-His vector (rxn 1). We could not just digest the citrine out because there is no upstream restriction site available. PCR with these primers will result in the addition of a NheI site on the end of the vector fragment near the promoter (to be ligated to the N terminus of the fusion protein), and a SexAI site on the end far from the promoter (to be ligated to the c terminus of the fusion protein) | ||
+ | b. In order to obtain the Nfluc fragment (1-398), we will PCR out that fragment via rxn 2 for green luciferase and rxn 3 for red luciferase. The primers for these two variants of luciferase are identical; the color determining point mutations are all located in this N terminal fragment in the aa 240-250 range; they do not affect the primers. This will produce an Nfluc fragment framed by an NheI site on the N terminus and a Kpn1 site on the c terminus. | ||
+ | c. In order to obtain the PhyB fragment, we will PCR it out of the florida plasmids via rxn 6. This is just the N terminus of the PhyB, residues 1-621, chosen to reduce background, as in our other experiments. This will produce an PhyB fragment framed by an KpnI site on the N terminus and a SexAI site on the c terminus. | ||
+ | 2. Post-PCR processing | ||
+ | a. All fragments will be purified using a PCR cleanup column | ||
+ | 3. Restriction digests | ||
+ | a. Vector backbone will be digested for 1 hr at 37 degrees with NheI and SexAI, Buffer 4 or 1 with BSA. | ||
+ | b. Nfluc fragment will be digested for 1 hr at 37 degrees with NheI and Kpn1, Buffer 1 with BSA. | ||
+ | c. PhyB fragment will be digested for 1 hr at 37 degrees with Kpn1 and SexAI, Buffer 1 with BSA | ||
+ | 4. Purification | ||
+ | a. All fragments will be purified using a PCR cleanup column | ||
+ | 5. Ligation Method 1—3 piece ligation (side by side with method 2) | ||
+ | a. All three fragments are added to the same ligation reaction (what fold excess of the two inserts? 3? 4?), incubated at 37 for 1 hour | ||
+ | b. Ligations are transformed into XL10 gold (because need sensitivity) | ||
+ | 6. Ligation Method 2—2 stage ligation (side by side with method 1) | ||
+ | a. The Nfluc and PhyB fragments are ligated for one hour, followed by PCR with the F.Nfluc and R.PhyB primers in order to amplify the ligated fragment | ||
+ | b. PCR product Nfluc-PhyB is digested with NheI and SexAI, followed by column purification | ||
+ | c. Purified Nfluc-PhyB insert is ligated to vector backbone fragment for 1hour at 37 with DNA ligase | ||
+ | d. Ligations are transformed into XL10 gold | ||
+ | |||
+ | Ura Vector + PIF3-Cfluc | ||
+ | 1. PCR Reactions | ||
+ | a. In order to obtain vector backbone without the inserted citrine, PCR around the pFA6a-Ura vector (rxn 1). We could not just digest the citrine out because there is no upstream restriction site available. PCR with these primers will result in the addition of a NheI site on the end of the vector fragment near the promoter (to be ligated to the N terminus of the fusion protein), and a SexAI site on the end far from the promoter (to be ligated to the c terminus of the fusion protein) | ||
+ | b. In order to obtain the PIF3 fragment, we will PCR it out of the florida plasmids via rxn 7 for full length PIF3 and rxn 8 for partial PIF3 (aa 1-100). This is just the N terminus of the PhyB, residues 1-621, chosen to reduce background, as in our other experiments. This will produce an PhyB fragment framed by an NheI site on the N terminus and a KpnI site on the c terminus. | ||
+ | c. In order to obtain the cfluc fragment (394-547), we will PCR out that fragment via rxn 4 for either luciferase. The primers for these two variants of luciferase are identical; the color determining point mutations are all located in this N terminal fragment in the aa 240-250 range; they do not affect the primers. This will produce an Cfluc fragment framed by an Kpn1 site on the N terminus and a SexAI site on the c terminus. This will also serve to introduce a stop codon at the end of the cfluc and remove the SKL peroxisomal targeting sequence located on aa 548-550. | ||
+ | 2. Post-PCR processing | ||
+ | a. All fragments will be purified using a PCR cleanup column | ||
+ | 3. Restriction digests | ||
+ | a. Vector backbone will be digested for 1 hr at 37 degrees with NheI and SexAI, Buffer 4 or 1 with BSA. | ||
+ | b. PIF3 fragment will be digested for 1 hr at 37 degrees with NheI and Kpn1, Buffer 1 with BSA. | ||
+ | c. Cfluc fragment will be digested for 1 hr at 37 degrees with Kpn1 and SexAI, Buffer 1 with BSA | ||
+ | 4. Purification | ||
+ | a. All fragments will be purified using a PCR cleanup column | ||
+ | 5. Ligation Method 1—3 piece ligation (side by side with method 2) | ||
+ | a. All three fragments are added to the same ligation reaction (what fold excess of the two inserts? 3? 4?), incubated at 37 for 1 hour | ||
+ | b. Ligations are transformed into XL10 gold (because need sensitivity) | ||
+ | 6. Ligation Method 2—2 stage ligation (side by side with method 1) | ||
+ | a. The PIF3 and Cfluc fragments are ligated for one hour, followed by PCR with the F.PIF3 and R.Cfluc primers in order to amplify the ligated fragment. This will be done for both the partial and full length PIF3. | ||
+ | b. PCR product PIF3-Cfluc is digested with NheI and SexAI, followed by column purification. This will be done for both the partial and full length PIF3. | ||
+ | c. Purified PIF3-Cfluc insert is ligated to vector backbone fragment for 1hour at 37 with DNA ligase | ||
+ | d. Ligations are transformed into XL10 gold | ||
+ | |||
+ | Attempt 1 at assembly of split luciferase system in yeast vectors | ||
+ | PCR Reaction Mixes | ||
+ | Mastermix | ||
+ | H2O 40.6 ul x5= 203ul | ||
+ | Buffer 5 ul x5= 25 ul | ||
+ | dNTPs 0.4 ul x5= 2 ul | ||
+ | PfuTurbo 1 ul x5= 5 ul | ||
+ | Per Reaction | ||
+ | Mix 47 uL mix per reaction | ||
+ | Fwd Primer 1 ul | ||
+ | Rev Primer 1 ul | ||
+ | DNA 1 ul | ||
+ | Total 50 uL per reaction | ||
+ | No. Product Frag. DNA Forward Reverse | ||
+ | 1 His- vector pFA6a-Act-His F. pFA6a.plasmid.SpL.SexAI R.pFA6a.plasmid.SpL.Nhe | ||
+ | 2 Ura- vector pFA6a-Act-Ura F. pFA6a.plasmid.SpL.SexAI R.pFA6a.plasmid.SpL.Nhe | ||
+ | 3 Red Nfluc Red luciferase F.Nfluc.SpL.NheI R.Nfluc.SpL.KpnI | ||
+ | 4 Green Nfluc Green luciferase F.Nfluc.SpL.NheI R.Nfluc.SpL.KpnI | ||
+ | 5 R/G Cfluc Red luciferase F.cFluc.SpL.KpnI R.Cfluc.SpL.SexAI | ||
+ | 6 PhyB Nterm PhyB florida F.PhyB.SpL.KpnI R.PhyB.SpL.SexAI | ||
+ | 7 PIF3 Full PIF3 florida F.PIF3.SpL.NheI R.PIF3.Full.SpL.KpnI | ||
+ | 8 PIF3 Partial PIF3 florida F.PIF3.SpL.NheI R.PIF3.partial.SpL.KpnI | ||
+ | |||
+ | |||
+ | Thermocycler Conditions | ||
+ | Ura and His Backbones | ||
+ | 1 cycle of 95 for 2 minutes | ||
+ | 5 cycles of 95 for 30 seconds | ||
+ | 45 for 30 seconds | ||
+ | 72 for 5 minutes | ||
+ | 25 cycles of 95 for 30 seconds | ||
+ | 52 for 30 seconds | ||
+ | 72 for 5 minutes | ||
+ | 1 cycle of 72 for 10 minutes | ||
+ | nFluc Red, nFluc Green, cFluc, PhyB, PIF3 full and partial | ||
+ | 1 cycle of 95 for 2 minutes | ||
+ | 30 cycles of 95 for 30 seconds | ||
+ | 52 for 30 seconds | ||
+ | 72 for 5 minutes | ||
+ | 1 cycle of 72 for 10 minutes | ||
+ | |||
+ | Check Gel All but PhyB appeared to work. | ||
+ | |||
+ | |||
+ | Digest Reaction Mixes | ||
+ | Number Product Frag. Digest Buffer | ||
+ | 1 His- vector SexAI/NheI/DpnI Buffer 4 + BSA @ 37, 1hr | ||
+ | 2 Ura- vector SexAI/NheI/DpnI Buffer 4 + BSA @ 37, 1hr | ||
+ | 3 Red Nfluc NheI/KpnI/DpnI Buffer 1 + BSA @ 37, 1hr | ||
+ | 4 Green Nfluc NheI/KpnI/DpnI Buffer 1 + BSA @ 37, 1hr | ||
+ | 5 R/G Cfluc KpnI/SexAI/DpnI Buffer 1 + BSA @ 37, 1hr | ||
+ | 6 PhyB Nterm KpnI/SexAI/DpnI Buffer 1 + BSA @ 37, 1hr | ||
+ | 7 PIF3 Full NheI/Kpn1/DpnI Buffer 1 + BSA @ 37, 1hr | ||
+ | 8 PIF3 Partial NheI/Kpn1/DpnI Buffer 1 + BSA @ 37, 1hr | ||
+ | |||
+ | |||
+ | Ligations and Transformations All ligations are 25 ng of vector and (a) are 1:3:3 vector:insert:insert, (b) are 1:1:1 vector:insert:insert | ||
+ | |||
+ | Ligation Product Vector ng uL Insert 1 Ng Ul Insert 2 Ng ul Buffer Ligase | ||
+ | 1A Red-Phy His 25 ng 10 ul RedN 18 ng 2 ul PhyB 27 ng 5 ul 1 ul | ||
+ | 1B Red-Phy His 25 ng 10 ul RedN 6 ng 1.3 ul PhyB 9 ng 5 ul 1 ul | ||
+ | 2A Gn-Phy—note: intended to be green but accidentally added red. His 25 ng 10 ul GreenN 18 ng 2 ul PhyB 27 ng 5 ul 1 ul | ||
+ | 2B Gn-Phy note: intended to be green but accidentally added red. His 25 ng 10 ul GreenN 6 ng 2 ul PhyB 9 ng 5 ul 1 ul | ||
+ | 3A PifFull-Cluc Ura 25 ng 16 ul cFluc 7.25 ng 0.35 ul PIF3 full 24 ng 4.8 ul 5 ul 1 ul | ||
+ | 3B PifFull-Cluc Ura 25 ng 16 ul cFluc 2.25 ng 0.13 ul PIF3 full 8 ng 1.6 ul 5 ul 1 ul | ||
+ | 4A PifPart-Cluc Ura 25 ng 16 ul cFluc 7.25 ng 0.35 ul PIF3 par 4.5 ng 1.6 ul 5 ul 1 ul | ||
+ | 4B PifPart-Cluc Ura 25 ng 16 ul cFluc 2.25 ng 0.13 ul PIF3 par 1.5 ng 0.5 ul 5 ul 1 ul | ||
+ | 6 Control His Control 6 ng 5 ul n/a n/a n/a n/a n/a n/a 5 ul 1 ul | ||
+ | 7 Control Ura Control 10 ng 5 ul n/a n/a n/a n/a n/a n/a 5 ul 1 ul | ||
+ | |||
+ | None of the plates had any colonies on them after transformation into 25 ul of XL10 gold cells each followed by immediate plating onto ampicillin plates (no incubation). The next day after ligating overnight we tried transforming them into Top10 chemically competent cells, this time with the full hour incubation. There were still no colonies. This is probably attributable to not enough backbone DNA present. Will have to reassess cloning strategy. | ||
+ | |||
+ | PCR redo on PhyB | ||
+ | PCR Reactions | ||
+ | 1. PhyB 221 (from Florida stock) | ||
+ | 2. PhyB Dest 22 (from Florida stock) | ||
+ | 3. PhyB 221 (our stock) | ||
+ | 4. PhyB Dest 22 (our stock) | ||
+ | Note: used primers at 100 ng/uL | ||
+ | |||
+ | H2O 40.6 ul x5= 203ul | ||
+ | Buffer 5 ul x5= 25 ul | ||
+ | dNTPs 0.4 ul x5= 2 ul | ||
+ | PrimerF 1 ul x5= 5 ul | ||
+ | PrimerR 1 ul x5= 5 ul | ||
+ | PfuTurbo 1 ul x5= 5 ul | ||
+ | Total 49 uL per reaction | ||
+ | |||
+ | Thermocycler conditions for PhyB | ||
+ | PhyB 221 original, PhyB Dest 22 original, PhyB 221 ours, PhyB Dest 22 ours | ||
+ | 1 cycle of 95 for 2 minutes | ||
+ | 30 cycles of 95 for 30 seconds | ||
+ | 45 for 30 seconds | ||
+ | 72 for 5 minutes | ||
+ | 1 cycle of 72 for 10 minutes | ||
+ | Check Gel for PhyB None of the 4 PCRs worked. Will need to reexamine the primer design. Reexamination found that I did design them incorrectly and they will have to be reordered. Damn. In the meantime I will focus on cloning of the PIF3-cFluc. Need to repeat the PCRs for the PIF3 and the cFluc | ||
+ | |||
+ | |||
+ | Redo of PCR for Ura and His Backbones | ||
+ | PCR Reactions | ||
+ | Mastermix | ||
+ | 25 ul Buffer | ||
+ | 5 ul DNTPs | ||
+ | 15 ul QuickChange Solution | ||
+ | 4 uL fwd primer 1A | ||
+ | 4 ul reverse primer 1B | ||
+ | 190 uL H20 | ||
+ | |||
+ | 49 uL mastermix reaction, plus 1ul of each of the following DNAs: 1) His, 2) His, 3)Ura, 4) Ura | ||
+ | Thermocycler conditions | ||
+ | 1 cycle of 95 for 2 minutes | ||
+ | 5 cycles of 95 for 30 seconds | ||
+ | 45 for 30 seconds | ||
+ | 72 for 5 minutes | ||
+ | 25 cycles of 95 for 30 seconds | ||
+ | 52 for 30 seconds | ||
+ | 72 for 5 minutes | ||
+ | 1 cycle of 72 for 10 minutes | ||
+ | Check Gel | ||
+ | Gel 1. Initial results of the 5 ul per well check gel were unclear—parent DNA band was visible, and there might have been a smeary band below it. Lane 1 is ladder, Lane 2 and 3 are His, Lane 4 and 5 are Ura, Lane 6 is ladder. 5 ul Ladder. | ||
+ | Gel 1 Gel 2 | ||
+ | |||
+ | |||
+ | Gel 2. To help determine if there was anything, the remainder of the reaction was subjected to a Dpn1 digest for 1 hr at 37 minutes and then 20 ul of the reaction were run out on a check gel. The parent band was gone, there was a ladder present, but no band indicative of product that we would expect around 5 kb. Lane 1 is ladder, Lane 2 and 3 are His, Lane 4 and 5 are Ura, Lane 6 is ladder. 5 ul 1 kb plus Ladder. | ||
+ | |||
+ | Troubleshooting the backbone PCR | ||
+ | Should email the Murray lab people and ask them if they have a different vector that we can use for this, one that actually has a site upstream of the gene inserted into it. David looked at my primers and did not see a significant problem with them, Tms are a little on the low side but there is not much to do about that. I will try to redesign them and in the meantime we have ordered a new PlatnumPfx from Invitrogen which should be more processive and get better yield. Also should I consider increasing the extension time? That might help. It was a problem with the luciferase when I didn’t give it long enough. | ||
+ | |||
+ | PCR of PhyB and Luciferase Nterminus for insertion into the pFA6a backbones. This is being done because we need the inserts for the creation of the split luciferase system in yeast. These fragments will be digested with Kpn1, ligated to eachother, and then PCR amplified for insertion into the pFA6a backbones from the Murray lab. | ||
+ | |||
+ | Name DNA Fwd Primer Reverse Primer | ||
+ | 221 PhyB SpL 221 from Mike stock F.PhyB.SpL.KpnI R.PhyB.SpL.SexAI.corrected | ||
+ | Dest PhyB SpL Dest from Mike stock F.PhyB.SpL.KpnI R.PhyB.SpL.SexAI.corrected | ||
+ | D155 PhyB SpL German with PhyB 2 F.PhyB.SpL.KpnI R.PhyB.SpL.SexAI.corrected | ||
+ | Luciferase-Red Red Luciferase stock F.nFluc.SpL.NheI R.nFluc.SpL.KpnI | ||
+ | Luciferase-Gn Gn luciferase stock F.nFluc.SpL.NheI R.nFluc.SpL.KpnI | ||
+ | |||
+ | |||
+ | |||
+ | Reaction Mixtures | ||
+ | PhyB for SpL PhyB for Luciferase | ||
+ | |||
+ | |||
+ | Thermocycler conditions | ||
+ | Phy B Luciferase | ||
+ | |||
+ | Check Gel | ||
+ | |||
+ | Lane (1) 221 PhyB SpL, (2) 221 PhyB pST39, (3) Dest PhyB SpL (4) Dest PhyB pST39 (5) D154 PhyB SpL, (6)D154 PhyB pST39, (7) Red Nfluc pST39, (8) Red Nfluc SpL, (9) Green Nfluc SpL, (10) Green Nfluc pST39. All lanes have bands of the correct sizes, all DNAs column purified and speced. | ||
+ | |||
+ | Purification PhyB for SpL (used Dest)- 16.7 ng/ul, PhyB for pST39 (used Dest)—30 ng/ul, Red for SpL 49.9, Red for pST39 35.4 ng/ul, Green for SpL 49.6, Green for pST39 52.9. | ||
+ | |||
+ | Digestion | ||
+ | MasterMix for all 6 digests | ||
+ | Kpn1 8ul | ||
+ | Dpn1 8ul | ||
+ | Buffer 1 52 ul | ||
+ | BSA 52 ul | ||
+ | |||
+ | 16 uL of mix per reaction , 50 uL of DNA per Rxn | ||
+ | Digested for 1 hr at 37 degrees. | ||
+ | |||
+ | Purification PhyB for SpL 19.5, PhyB pST39 32.9 ng/ul, Red SpL 55 ng/ul, Red pST39 22.1 ng/ul, Green SpL 48.0 ng/ul, Green pST39 41.7 ng/ul. | ||
+ | |||
+ | Ligation | ||
+ | |||
+ | PCR Amplification | ||
+ | |||
+ | Red-PhyB Spl (A) Green-PhyB-SpL (B) Red-PhyB pST39 © Green-PhyB pST39 (D) | ||
+ | |||
+ | Check gel | ||
+ | |||
+ | |||
+ | PCR amplification of the Backbones from Ura and His take 4 | ||
+ | Tried PCR with old Platinum Pfx kit, annealing temps 52x5 cycles, 57x30 cycles, but according to Amy, no success. See her notes. | ||
+ | |||
+ | PCR amplification of the Backbones from Ura and His take 5 | ||
+ | Tried PCR again with new Platinum Pfx kit, and using the thermal gradient cycler, ranging temps from 50-70 to optimize annealing temperature. Hopefully something will work. | ||
+ | |||
+ | Set 1: pJHK043, at the temperatures below. 30 ul reactions each. | ||
+ | Set 2: pJHK063, at the temperatures below. 30 ul reactions each. | ||
+ | Sample 1) 50, 2) 50.5, 3) 51.7, 4) 53.2, 5) 53.5, 6) 58.4, 7) 61.8, 8) 64.6, 9) 66.8, 10) 68.4, 11) 69.6 12) 70.0 | ||
+ | |||
+ | Pooled the first 7 for each pJHK043 and pJHK063 and column purified them, concentration for pJHK043 288 ng/ul, pJHK063 343 ng/ul or something like that. | ||
+ | Inserts digested with SexAI and NheI | ||
+ | Vectors digested with SexAI, NheI, and DpnI | ||
+ | |||
+ | </p> | ||
<h3> Week 6: 7/13/09 - 7/17/09 </h3> | <h3> Week 6: 7/13/09 - 7/17/09 </h3> | ||
- | <p> | + | <p> Cloning into the Bacterial Vector, pST39 |
+ | The plasmid contains 4 sets of restriction sites for insertion of genes: | ||
+ | 1. XbaI/BamHI | ||
+ | 2. EcoRI/HindIII | ||
+ | 3. SacI/KpnI | ||
+ | 4. BspEI/MluI | ||
+ | We want to clone in 4 genes: Ho1, PcyA, nFluc-PhyB, PIF3-cFluc (partial and full). Which gene is to be put into which site was determined by comparing the list of sites (and complementary cutters) with the list of absent sites in the genes of interest. It was important to also look at complementary cutters because otherwise the cloning would not be possible (proper sites were not available) | ||
+ | • PcyA can go into sites 1, 3, 4 | ||
+ | • Ho1 can go into sites 1, 2, 3,4 | ||
+ | • PhyB can go into sites 1, 4 | ||
+ | • PIF3 can go into sites 1, 4 | ||
+ | Based on this list, genes will be inserted as follows: | ||
+ | • Site 1—nFluc-PhyB | ||
+ | • Site 2—Ho1 | ||
+ | • Site 3—PcyA | ||
+ | • Site 4—PIF3-cFluc | ||
+ | |||
+ | PCRs—Ho1 and PcyA we have from the registry, sequenced and confirmed. We will PCR them out of the miniprepped stocks that we have in the lab. nFluc-PhyB, PIF3-cFluc will be PCRed out of the yeast vectors once those constructs are made. | ||
+ | |||
+ | Insertion of the PCB synthesis genes—will try to insert both genes simultaneously into different pST39 vectors, then work with the one that takes the insert to insert the second biosynthesis gene. Whichever one works first we go with | ||
+ | 1. Ho1—Site 2: | ||
+ | a. PCR the insert out of existing Ho1 containing plasmids from the registry with F.Ho1.pST39.EcoRI and R.Ho1.pST39.HindIII primers, followed by gel purification of desired fragment (expected size 760 bp). | ||
+ | b. Cut the PCRed insert with EcoRI/HindIII (Buffer 2), followed by PCR cleanup column. | ||
+ | c. Cut the pST39 with EcoRI/HindIII (Buffer 2), followed by PCR cleanup column to remove enzymes. | ||
+ | d. Ligate the vector fragment and the insert fragment using QuikLigase | ||
+ | e. Transform the ligated plasmid into E coli, pick colonies, grow overnight, miniprep, diagnostic digest to test for insertion. | ||
+ | 2. PcyA—Site 3: | ||
+ | a. PCR the insert out of existing Ho1 containing plasmids from the registry with F.PcyA.pST39.SacI and R.PcyA.pST39.KpnI primers, followed by gel purification of desired fragment (expected size 790 bp). | ||
+ | b. Cut the PCRed insert with SacI/KpnI (Buffer 1), followed by PCR cleanup column. | ||
+ | c. Cut the pST39 with SacI/KpnI (Buffer 1), followed by PCR cleanup column to remove enzymes. | ||
+ | d. Ligate the vector fragment and the insert fragment using QuikLigase. | ||
+ | e. Transform the ligated plasmid into E coli, pick colonies, grow overnight, miniprep, diagnostic digest to test for insertion. | ||
+ | Insertion of the fusion proteins | ||
+ | 3. nFluc-PhyB—Site 1: | ||
+ | a. PCR the insert out of nFluc-PhyB fusion plasmids (yeast pFA6a) with F.nFluc.pST39.NheI and R.PhyB.pST39.BclI primers, followed by gel purification of desired fragment (expected size 1800 bp). | ||
+ | b. Cut the PCRed insert with NheI/BclI (Buffer 2, 37 for 1 hour, add BclI then 50 for 1 hour), followed by PCR cleanup column. | ||
+ | c. Cut the pST39-PCB with XbaI/BamHI (Buffer 3), followed by PCR cleanup column to remove enzymes. | ||
+ | d. Ligate the vector fragment and the insert fragment using QuikLigase. | ||
+ | e. Transform the ligated plasmid into E coli, pick colonies, grow overnight, miniprep, diagnostic digest to test for insertion. | ||
+ | 4. PIF3partial-cFluc—Site 4: | ||
+ | a. PCR the insert out of PIF3partial-cFluc fusion plasmids (yeast pFA6a) with F.PIF3.pST39.XmaI and R.cFluc.pST39.MluI primers, followed by gel purification of desired fragment (expected size 800 bp). | ||
+ | b. Cut the PCRed insert with XmaI/MluI (Buffer 4), followed by PCR cleanup column. | ||
+ | c. Cut the pST39-PCB-PhyB with BspeI/MluI (Buffer 3), followed by PCR cleanup column to remove enzymes. | ||
+ | d. Ligate the vector fragment and the insert fragment using QuikLigase. | ||
+ | e. Transform the ligated plasmid into E coli, pick colonies, grow overnight, miniprep, diagnostic digest to test for insertion. | ||
+ | 5. PIF3full-cFluc—Site 4: | ||
+ | a. PCR the insert out of PIF3full-cFluc fusion plasmids (yeast pFA6a) with F.PIF3.pST39.XmaI and R.cFluc.pST39.MluI primers, followed by gel purification of desired fragment (expected size 2100 bp). | ||
+ | b. Cut the PCRed insert with XmaI/MluI (Buffer 4), followed by PCR cleanup column. | ||
+ | c. Cut the pST39-PCB-PhyB with BspeI/MluI (Buffer 3), followed by PCR cleanup column to remove enzymes. | ||
+ | d. Ligate the vector fragment and the insert fragment using QuikLigase. | ||
+ | e. Transform the ligated plasmid into E coli, pick colonies, grow overnight, miniprep, diagnostic digest to test for insertion. | ||
+ | |||
+ | |||
+ | Designing Primers for Cloning into the pST39 vector for Bacterial expression | ||
+ | Site 1: XbaI/BamHI: Nfluc-PhyB (NheI/BclI) | ||
+ | F.nFluc.pST39.NheI AAG CTT GCT AGC AAA atggaagacgccaaaaacataaag | ||
+ | R.PhyB.pST39.BclI AAG CTT TGA TCA AAA ttaaagctggagcgagtgaatc | ||
+ | |||
+ | Site 2: EcoRI/HindIII: Ho1 | ||
+ | F.Ho1.pST39.EcoRI TAG CTT GAA TTC AAA atgagtgtcaacttagcttccc 47/52 | ||
+ | R.Ho1.pST39.HindIII TAG CTT AAG CTT AAA ttattagccttcggaggtggcg 57/52 | ||
+ | |||
+ | Site 3: SacI/KpnI: PcyA | ||
+ | F.PcyA.pST39.SacI TAG CTT GAG CTC AAA atggccgtcactgatttaagtttg 57 | ||
+ | R.PcyA.pST39.KpnI TAG CTT GGT ACC AAA ttattggataacatcaaataag 45/49 | ||
+ | |||
+ | Site 4: BspE1/MluI: PIF3-Cfluc (xmaI/MluI) | ||
+ | F.PIF3.pST39.XmaI TAG CTT CCC GGG AAA atgcctctgtttgagcttttc 54 | ||
+ | R.cFluc.pST39.MluI TAG CTT ACG CGT AAA ttactttccgcccttcttggcc 60 | ||
+ | |||
+ | |||
+ | To Do Today | ||
+ | 1. Do minipreps of pST39, and digest for ligations, column purification, ligation | ||
+ | 2. Do PCRs of the PcyA and Ho1, followed by check gel, column purification, digest incl DpnI, column purification, ligation into pST39 | ||
+ | 3. Do PCRs of split luciferase plasmids, check gel, column purification, digest with KpnI and DpnI, column purification, ligation, PCR of fragment, check gel, column purification digest with SexAI and NheI, column purification, ligation to backbone | ||
+ | 4. Do purifications of vector backbone, digest with NheI, SexAI and DpnI, and | ||
+ | |||
+ | PCRs to do | ||
+ | 1. PcyA | ||
+ | 2. Ho1 | ||
+ | 3. PIF3 full | ||
+ | 4. PIF3 partial | ||
+ | 5. cFluc | ||
+ | |||
+ | |||
+ | Need to make plasmid of | ||
+ | 1. pST39 (do minipreps of cultures today) | ||
+ | 2. Murray Lab plasmid 17 (pick colonies, do minipreps tomorrow) | ||
+ | 3. Murray lab plasmid 18 (pick colonies, do minipreps tomorrow) | ||
+ | |||
+ | |||
+ | Insertion of Ho1 into pST39 | ||
+ | PCR for amplification of PcyA and Ho1 | ||
+ | PcyA Ho1 | ||
+ | 5 ul Thermopol Buffer 5 ul Thermopol Buffer | ||
+ | 1 ul DNTPs 1 ul DNTPs | ||
+ | 1 ul fwd primer F.PcyA.pST39.SacI 1 ul fwd primer F.Ho1.pST39.EcoRI | ||
+ | 1 ul reverse primer R.PcyA.pST39.KpnI 1 ul reverse primer R.Ho1.pST39.HindIII | ||
+ | 1 ul DNA PcyA 1 ul DNA Ho1 | ||
+ | 40 ul H20 40 ul H20 | ||
+ | 1 ul VENT enzyme 1 ul VENT enzyme | ||
+ | |||
+ | Ho1 was amplified successfully (~700bp), PcyA showed an incorrect band between 1 and 1.65kb. This was the same band that Jen and Ivan saw, will repeat that PCR with a higher annealing temperature. | ||
+ | |||
+ | Digests of Ho1 and pST39 | ||
+ | Ho1 (PCR product purified by Amy) pST39 (DNA minpreped by Anu) | ||
+ | 1 ul DPN1 | ||
+ | 1 ul EcoRI 1 ul EcoRI | ||
+ | 1 ul HindIII 1 ul HindIII | ||
+ | 6.5 uL Buffer 2 3 uL Buffer 2 | ||
+ | 6.5 ul BSA 3 ul BSA | ||
+ | 50 uL DNA 22 uL DNA | ||
+ | Total 66.5 uL Total 30 uL | ||
+ | |||
+ | Digested for 1 hr at 37 degrees, followed by column purification and elution into 50 uL water. | ||
+ | Concentrations after purification: HO1: 15.1 ng/ul, pST39 11.5 ng/ul | ||
+ | |||
+ | Ligation Mix the following: | ||
+ | Ligation pST39 negative control Ho1 negative control | ||
+ | 50 ng pST39 → 4.4 uL of pST39 fragment 4.4 ul pST39 fragment | ||
+ | 36 ng HO1 (for a 3:1 ratio) → 2.4 ul HO1 fragment 2.4 uL Ho1 fragment | ||
+ | 10 ul water 15 uL water 15 uL water | ||
+ | |||
+ | Heat for 5 minutes at 45 degrees do denature any annealed ends, Cool on ice | ||
+ | Add 2 uL ligase buffer and 0.5 uL ligase to each reactoin | ||
+ | Incubate at 14 degrees C for 2-4 hours. (actually incubated for 2 hours) | ||
+ | Transformation Transformed into TOP10 cells. Plates yielded numerous colonies. | ||
+ | |||
+ | Colony PCR | ||
+ | Rxn Mix for 10 reactions: | ||
+ | 10 uL 10x –MG buffer | ||
+ | 2 uL 10 nM dNTP mix | ||
+ | 3 uL 50 nM MgCl2 | ||
+ | 2.5 uL Primer Fwd F.luciferase.BamHI | ||
+ | 2.5 uL Primer Rev R.luciferase.SalI | ||
+ | 5 uL Taq | ||
+ | 80 uL Water | ||
+ | Then, 10 uL aliquots were made, and ½ a culture added to each one, for a total of 10 reactions. | ||
+ | |||
+ | Thermocycler conditions (1) 95 for 6 min. 2) 95 for 45 seconds. 3) 45 for 30 seconds. 4) 72 for 1 min. 5) Go to 2 4 more times. 6) 94 for 45 seconds. 7) 50 for 30 seconds. 8) 72 for 1 minute. 9) Go to 6 24 more times. 10) 72 for 10 min. 11) 4 for 24 hours, 12) End. | ||
+ | |||
+ | Gel Colony PCR indicated that almost all colonies contained the insert, HO1, which is approx 700 bp, as seen in the gel, wells 1-4. I have picked and grown up those colonies, and miniprepped them. Concentrations were low, but that is expected given that the plasmid is low copy number. Approx 10x lower in copy number expected, and concentrations were about 30 ng/ul, 10x lower than a 2 mL miniprep of a high copy number plasmid would typically yield. The last two lanes of this gel are PhyB redo pcrs, which once again did not work. | ||
+ | |||
+ | |||
+ | Insertion of PcyA into pST39 (containing HO1) to make pST39-PCB | ||
+ | Redo of PcyA PCR | ||
+ | PcyA | ||
+ | 5 ul Thermopol Buffer | ||
+ | 1 ul DNTPs | ||
+ | 1 ul fwd primer F.PcyA.pST39.SacI | ||
+ | 1 ul reverse primer R.PcyA.pST39.KpnI | ||
+ | 1 ul DNA PcyA | ||
+ | 40 ul H20 | ||
+ | 1ul VENT enzyme | ||
+ | Thermocycler conditions (1) 95 for 5 min. 2) 95 for 30 seconds. 3) 47 for 30 seconds (increased from 42 last time, don’t remember). 4) 72 for 1 min. 5) Go to 2 4 more times. 6) 95 for 30 seocnds. 7) 53 for 30 seconds. 8) 72 for 1 minute. 9) Go to 6 24 more times. 10) 72 for 5 min. 11) 4 for 24 hours, 12) End. | ||
+ | |||
+ | Check Gel Results We did get the correct 750 bp band, to be ligated into the plasmid tomorrow! I don’t have an image for this, it was on an agarose gel Ivan ran, they just used one lane of it for me. | ||
+ | |||
+ | PcyA Purification | ||
+ | Digest of PcyA and pST39-HO1 to make pST39-PCB | ||
+ | PcyA pST39-Ho1 | ||
+ | 1 ul Sac1 1 ul Sac1 | ||
+ | 1 ul Kpn1 1 ul Kpn1 | ||
+ | 1 ul Dpn1 | ||
+ | 3 ul Buffer 1 3 uL Buffer 1 | ||
+ | 3 uL BSA 3 uL BSA | ||
+ | Digest 1 hr at 37 (AMY) | ||
+ | PCR cleanup column (AMY) | ||
+ | Ligate PcyA into pST39-Ho1 to make pST39-PCB (AMY) | ||
+ | Transform and plate onto Amp plates (AMY) | ||
+ | Colony PCR on 20 colonies from pST39-PCB plates | ||
+ | Mastermix | ||
+ | 22 uL 10x buffer | ||
+ | 4.1 uL DNTPS | ||
+ | 6.2 uL MgCl2 | ||
+ | 5 uL F.PcyA | ||
+ | 5 uL R.PcyA | ||
+ | 1.5 uL Taq | ||
+ | 170 uL water | ||
+ | |||
+ | 10 uL per reaction x 20 colonies | ||
+ | |||
+ | Gels show a band at the bottom which is probably primers, and colonies 12, 14, 15, 16, 16, 17, 18, and 19 showed a band at ~700, which is the right size for PcyA! Success! Those colonies will then be picked, grown up, and diagnostic digested for PcyA and HO1. | ||
+ | |||
+ | Minipreps of Colonies: 12) 16.2 ng/ul, 14)17.1 ng/ul, 15)10.8 ng/ul, 16)14.5 ng.ul, 17)14.4 ng/ul, 18)15.0 ng/ul, 19) 15.1 ng/ul | ||
+ | |||
+ | Diagnostic Digests of pST39-PCB | ||
+ | Mix for HO1 Mix for PcyA | ||
+ | 8 ul EcoRI-HF 8 ul SacI | ||
+ | 8ul HindIII 8 uL KpnI | ||
+ | 24 ul Buffer 2 24 uL Buffer 1 | ||
+ | 24 uL BSA 24 uL BSA | ||
+ | 96 uL Water 96 uL water | ||
+ | |||
+ | 20 ul mix per reaction, 10 uL DNA. | ||
+ | |||
+ | 1-7 are digests of 12, 14, 15, 16, 17, 18, 19 for Ho1 (using EcoRI-HF and HindIII) | ||
+ | |||
+ | |||
+ | If the plasmids in fact contained the genes of interest, there should have been a 700 or 750 bp band in each. My hopes that the enzymes just didn’t cut properly were also dashed because the band that is there is about 2.9 kb, which is the size of the original plasmid sent by the Tan lab. | ||
+ | |||
+ | Insertion of PIF3-cFluc into pST39-PCB | ||
+ | |||
+ | |||
+ | |||
+ | Designing mutagenesis primers for pST39-PCB-PIF3 | ||
+ | Need to mutagenize the Xba site located at nucleotide 175 in PIF3 sequence because it will cause significant problems with insertion of the PhyBNterm into the plasmid for construction of the vector. | ||
+ | Original: CACAAGCAAACTCTTCTAGAGCTAGAGAGATTGGAAATGG | ||
+ | Mutagenesis primer F.PIF3.RemoveXbaI: CACAAGCAAACTCTTCGAGAGCTAGAGAGATTGGAAATGG | ||
+ | R.PIF3.RemoveXbaI: CCATTTCCAATCTCTCTAGCTCTCGAAGAGTTTGCTTGTG | ||
+ | |||
+ | Insertion of nFluc-PhyB into pST-PCB-PIF3-cFluc to make pST39-PCB-SpL aka pST39-iGEM09 | ||
+ | PCR of PhyB and Luciferase Nterminus for insertion into the pST39 backbones. This is being done because we need the inserts for the creation of the split luciferase system in bacteria. These fragments will be digested with Kpn1, ligated to eachother, and then PCR amplified for insertion into the pST39-PCB backbones. | ||
+ | |||
+ | |||
+ | |||
+ | Creation of Strains for Testing Two Hybrid System | ||
+ | • Yeast were transformed with 1ug of each of the two hybrid plasmids, PhyB in the German vector fused to the Gal4 Binding Domain, and PIF3 in the pACT2 vector, fused to the Gal4 activation domain. Both of those plasmids are high copy number with a 2 micron origin of replication. pACT2 has a Leu2 marker, and Trp1 in the D153dh-phyA FL. | ||
+ | o Y190 yeast cells. Grown on LEU- TRP- plates. | ||
+ | o Cells were grown for 16-20 hours in PCB under red light, and the negatives were in the 30 degree in the dark room. Plates were coated with PCB at approx 50 uM (based on a rough approximation because it was a crude extract. 100x stock concentration, when Jen dried it as a powder we are under assumption it is pure PCB, so bc paper called for 24 umol, we used 50 uM because we have not HPLC purified it. Purified would probably work better, but our PCB is working). 20 uL extract in 480 uL DMSO, thickly coat a plate, let it dry in incubator for 10-20 min leaves a surface coating of PCB. Crude extract is working! In general everything preincubated in the dark, first with PCB, then subjected to light for another day. Minimum 16 hours in the dark for everything, minimum 16-20 hours. Then followed by 20-24 hours in red light. Plates put in about 5, at 5 developed. | ||
+ | o Developing—an x gal filter lift assay—Z buffer with BME supplemented. Xgal at 1mg/ml, a 50 mg/ml stock is made in DMF. 3 mL soaked on two whatman filter paprs, use nitrocellulose with rough side facing cells, when you see nitrocellulose moist, lift it off using forceps, and lift the colonies on. Let it float on aluminum boat for 20 seconds slowly freezing it, then 2 sec in liquid nitrogen. Let thaw 30 seconds to crack open yeast. Put it cell side up onto filter pads with zbuffer, and then 20 min to an hour you should see blue developments, which get more intense as time goes on. If you leave more than a day you get background blue. In a few days everything turns blue. | ||
+ | o We have repeated 3x the X gal assay to make sure the 2 hybrid system is working. Proof that the constructs work, proof that the PCB works. Those cells can then be transformed with HO endonuclease, or with Gal1-luciferase. Only grow them with PCB when you are going to do the light assay, so not in the liquid culture. Oliver could not get that to work. Need to find those two original constructs and hopefully we have some DNA left for additional transformations to make more functional yeast strains. | ||
+ | • These are PIF3 full length. The one that was partial did not work—we could try re-replica plating it but the PIF3 full was the only one that worked. There were 2 more PIF3 subclones that did not work. | ||
+ | • Ones that are turning really blue may have more copies of the plasmids, which risks that they might lose copies over time. We should make more stocks of the plasmids from those subclones that works. | ||
+ | |||
+ | |||
+ | |||
+ | Ivan: YipDCE1 (containing HO1 PcyA) integrate into ADE2 locus in yeast. Can we just add ferreoxin? We can grow them on glucose…we would rather adjust conditions than do genetic manipulation. | ||
+ | |||
+ | Characterization of the system | ||
+ | Dose response | ||
+ | Waiting for expression timescale | ||
+ | PCB titration | ||
+ | Sensitivity at different wavelengths | ||
+ | Resolution | ||
+ | |||
+ | Other things to do | ||
+ | Picking more strains | ||
+ | Coculture | ||
+ | |||
+ | Blackboard: | ||
+ | Optical communication—Oliver and Amrita | ||
+ | Characterization: PCB, Time exposure, Wavelength—Oliver and Amrita and Gosia | ||
+ | Red light district: HO Endonuclease—Anu and Neena | ||
+ | PCB biosynthesis—Jen and Ivan | ||
+ | Knocking out Ura locus—Oliver | ||
+ | Cloning—Amy with Ivan and Amrita and Jen | ||
+ | </p> | ||
<h3> Week 7: 7/20/09 - 7/24/09 </h3> | <h3> Week 7: 7/20/09 - 7/24/09 </h3> | ||
- | <p> | + | <p> Redoing the Split Luciferase Cloning into the TEF1 integrating vectors |
+ | We are getting 3 different TEF1 integrating vectors from Addgene, p404TEF1, p405TEF1, and p406TEF1. We gave up on the previous cloning plan because the promoter was probably not strong enough, and because it was a stupid plan for cloning anyway. | ||
+ | p404TEF1 Trp, Amp resistant, Very strong promoter, integrating http://www.addgene.org/pgvec1?f=c&cmd=findpl&identifier=15972 | ||
+ | p405TEF1 Leu, Amp resistant, Very strong promoter, integrating http://www.addgene.org/pgvec1?f=c&identifier=15968&atqx=p405TEF1&cmd=findpl | ||
+ | p406 TEF1 Ura, Amp resistant, Very strong promoter, integrating http://www.addgene.org/pgvec1?f=c&identifier=15976&atqx=p406TEF1&cmd=findpl | ||
+ | |||
+ | nFluc-PhyB (red or green) will be inserted into p405TEF1—Leu | ||
+ | 1. PCR: nFluc F.Nfluc.SpL.NheI (for both Red and Green) | ||
+ | R.Nfluc.SpL.KpnI | ||
+ | PhyB F.PhyB.SpL.KpnI | ||
+ | R.PhyB.pST39.BclI.correct | ||
+ | 2. Digests P405TEF1—XbaI (or SpeI)/BamHI | ||
+ | nFluc—NheI/KpnI (NheI ligates to XbaI) | ||
+ | PhyB—BclI/KpnI (BclI ligates to BamHI) | ||
+ | 3. Ligations—given the success of the three part ligation into the pST39 vector, I will do these as three part ligations; if those do not work we will PCR amplify the ligated insert | ||
+ | |||
+ | PIF3-cFluc will be inserted into p404TEF1—Trp | ||
+ | 1. PCR PIF3 full F.PIF3.SpL.XmaI | ||
+ | R.PIF3.Full.SpL.KpnI | ||
+ | PIF3 partial F.PIF3.SpL.XmaI | ||
+ | R.PIF3.Partial.SpL.KpnI | ||
+ | cFluc F.cFluc.SpL.KpnI | ||
+ | R.Cfluc.SpL.EcoRI | ||
+ | 2. Digests P404TEF1—XmaI/EcoRI | ||
+ | PIF3—XmaI/KpnI | ||
+ | cFluc—KpnI/EcoRI | ||
+ | 3. Ligations—three part ligations; if those do not work we will PCR amplify the ligated insert | ||
+ | |||
+ | |||
+ | PIF3 ligations appeared to yield colonies, but PhyB ligations did not. I think this is attributable to the difference in sizes. PIF3 full is 1600, PIF3 partial is 300, cFluc is 450, PhyB is 1800, nFluc is 1200, so the combination of the 1200+1600 into the 6 kb vector may be too much. This is based on the fact that the PIF3 partial with the smallest inserts has a lot of colonies but the PIF3 full has only a handful. There are a couple of things to try. | ||
+ | 1. PCR amplify the ligated PhyB and nFluc inserts | ||
+ | a. Ligate the PCR amplified fragments for 1hr at 16 degrees using T4 | ||
+ | b. Ligate the PCR amplified fragments for 24 hours at 4 degrees | ||
+ | 2. Redo the same three part ligation | ||
+ | a. Ligate 1 hr at 16 degrees using T4 | ||
+ | b. Ligate 24 hours at 4 degrees | ||
+ | 3. Redo the PCR, digests, and ligations with new fragments | ||
+ | a. PCR | ||
+ | b. Purify | ||
+ | c. Digest | ||
+ | d. CIP | ||
+ | e. Purify | ||
+ | f. Ligate | ||
+ | |||
+ | |||
+ | |||
+ | |||
+ | DBD-PhyB (Nterminal 1-621) | ||
+ | PIF3-AD (full or partial) | ||
+ | </p> | ||
<h3> Week 8: 7/27/09 - 7/31/09 </h3> | <h3> Week 8: 7/27/09 - 7/31/09 </h3> | ||
- | <p> | + | <p> Bacteria to Yeast Communication Experiments |
+ | |||
+ | Your browser may not support display of this image. Your browser may not support display of this image. | ||
+ | |||
+ | Per Oliver: " Using light as a trans-acting factor to optically bridge a physically separated canonical lac operon"...almost sounds like it belongs in a textbook. | ||
+ | And it just so happens that the P-gex6p2 plasmid is regulated by LacI (which is inhibited by the non-metabolizable allolactose analog IPTG) and our receiver output is encoded by LacZ (which cleaves the galactose analog X-gal or ONPG). Who says B-gal output is BORING?...only if we present it as, "yeah, so the cells turned blue when this gene turned on when it saw red light which came from some other cell that made luciferase....Now we have some historical context. Jacob and Monod would approve.” | ||
+ | |||
+ | Bacteria to Yeast Communication Experiment 1—Small bacterial petri dish sitting on large yeast petri dish. | ||
+ | |||
+ | Two mls of bacterial culture were grown overnight, then incubated with luciferase and placed in a sterile petri plate. That petri plate was placed on top of PIF3/PhyB yeast growing on Trp-/Leu- media. In order to test light-based communication between bacteria and luciferase, bacteria were transformed with luciferase plasmids under constitutive promoter, and expressed red lucifeerase. Cells grown overnight, spun down, resuspended in 4ml sodium citrate buffer with 1 mMolar luciferin. Yeast were grown from plate 2 that was apparently light sensitive grown on PCB plates overnight, and then small petri dish with resuspended luciferase bacteria placed on center of yeast plate. Sealed and put in incubator over night. Tomorrow will do filter lifts and assay for beta-gal expression. Hopefully will have circle of expressing. Cells are almost a lawn. | ||
+ | |||
+ | Your browser may not support display of this image. | ||
+ | |||
+ | Bacteria to Yeast Communication Experiment 2—separated by petri dish, increased number of bacterial cells | ||
+ | |||
+ | In this experiment the bacteria were placed in a small petri dish in the center of the plate contining yeast growing on solid agar. There is blue on the Bacterial light + PCB plate, but not on any of the negative controls. This is proof of principle that red light from bacteria can excite the system!!!! | ||
+ | |||
+ | Your browser may not support display of this image. Your browser may not support display of this image. Your browser may not support display of this image. Your browser may not support display of this image. | ||
+ | |||
+ | Bacteria to Yeast Communication in Solid Media Separated by Petri dish-- Experiment 3 | ||
+ | |||
+ | Take 1: Bacteria have been IPTG inducing for 7 hours now. 10 mMol IPTG. This is from an overnight culture, 25 mL of 2xYT. Used frozen stock of cells, Red Luciferase in the PGEX IPTG inducible plasmid. At 1pm overnight bacterial culture was split and IPTG induction begun. Did 1 in 10 dilution (5mL cells into 50ml 2xYT with amp). One was IPTG induced with 10 mMol, .238 g for 100 mL culture. One culture was not IPTG induced. There was another culture that was not from frozen stock but was from plate. PDCE plasmid that was from an Ecoli transformation plate with amp resistance as a negative control, not expressing luciferase. That was into 70 mL YT with 70uL amp. That has been growing for 7+ hours as well. Overnight inoculations had been done at 11pm. | ||
+ | |||
+ | Yeast—two 2mL cultures growing, one with DMSO, 50 uMol (40uL of 100x PCB stock, which we assume to be 50uMol final concentration, we assume majority is Phycocyanobilin). That was inoculated last night at 1030pm. Still in the incubator at 30 degrees in the dark. They have been in there for 22 hours. 16 hours in PCB is recommended. | ||
+ | |||
+ | It is probably a very saturated culture, not growing well though. That is the problem. Ideally we should split those cells and let them recover for a while…how crucial is that? We will do it tonight and again tomorrow. We have yeast that have been recovering for 2 hours (washed). We could throw them all together—Oliver was going to do a laser timecourse. For the laser timecourse, | ||
+ | |||
+ | Because it got too late we eneded up not doing this experiment on the night of Aug 4, we are going to actually do it on Aug 5. | ||
+ | |||
+ | Take 2: Bacterial cells were IPTG induced beginning at 1pm. Apparatus for suspensions of luciferase bacteria was constructed by crazygluing the lid of a small petri dish to the inside of the lid of a larger one, and a hole melted into the top to create a way to inject the cells into the pocket thus created. See images on camera. 2x 15 mL cultures of IPTG uinduced bacteria were spun down and resuspended in 5 mL ea. Sodium citrate buffer with 1 mmol luciferin. An addition 40 UL of 100 mMol luciferin was spiked in and seen to result in an increased luminescent signal by eye. 4 mL of bacteria were placed in the holding chamber for both PCB treated yeast and DMSO treated yeast. Two additional negative controls were also done, PCB treated yeast and DMSO treated yeast without bacteria. 50 ul of 100 mmol luciferin was spiked in at 1 hour, 2 hours, and 3 hours. Large mirrors were placed below the plates and small above, and the whole shebang wrapped in foil and placed on a shaking incubator at 30 degrees. By eye it was difficult to see luminescence at 1 or 2 hours, even though initial luminescence was extremely bright. Luminescence at 1 hour was clearer with coculture. | ||
+ | |||
+ | The result of this experiment was negative. There was no visible blue on any of the plates, more or less. This experiment will need to be repeated. | ||
+ | |||
+ | This is an image of the bacteria-yeast communication apparatus we designed so that the bacteria would not have to sit right on the yeast plate and therefore kill everything under it. There is one main hole for aeration and allowing us to spike in luciferase, and a smaller vent hole. The smaller dish is glued to the inside of the lid so that there is a 2 mm gap between it and the surface of the agar on which the yeast are growing. | ||
+ | |||
+ | Your browser may not support display of this image. | ||
+ | |||
+ | Bacteria and Yeast Coculture—Liquid—Experiment 1. | ||
+ | |||
+ | 0.5 mL yeast and 2 ml bacteria in 5 umol luciferin. At the end of the timepoints spin those down atmax speed, pellet them put them in -80. Tomorrow will do an ONPG assay or something. 1. PCB yeast + glowing bacteria, 2. One with no PCB + glowing bacteria. 3. One with PCB yeast and nonglowing bacteria. Cells were spiked with 20 uL of 100 mMol luciferin at 1hr, 2hr, and then spun down and frozen at-80 degrees at 3 hours. Will be xgal and onpg assayed. As of 8/10 they are still in the freezer, this assay will probably have to be redone because of the age of the cultures. | ||
+ | |||
+ | Bacteria to Yeast Communication in Solid Media Separated by Petri dish-- Experiment 4. Changing speed of shaking; More aeration holes | ||
+ | |||
+ | Bacterial cells IPTG induced at 11:30 am, to grow for 5 hours, and be spun down at 3:30, for 4 hours of induction and assay begun at 4. 150 mL of medium inoculated with 10 mL of bacteria from overnight culture and 0.75 g IPTG added. Spiking with luciferase once an hour until 7. Dinner at 7. We made several changes in this attempt: we increased the shaking speed, and increased the number of aeration holes. This meant bacteria splashed out everywhere, and needed to be replenished at 11 pm (after 4 hours of IPTG induction). However, I also forgot to put the lid apparatuses on the yeast plates. Epic fail. Therefore there was no data from this experiment because we had a signal, but no receiver. However, the cells were kind of old so it’s ok. We will repeat Tuesday. | ||
+ | |||
+ | Your browser may not support display of this image. | ||
+ | |||
+ | |||
+ | Bacteria to Yeast Communication in Solid Media: Experiment 5—Using smaller dish, supplementing medium with Histidine, actually using the yeast plates, using fresh cultures. | ||
+ | |||
+ | Prepared small plates for assay using: 25 mL agar, 2.5 mL 10x dropout medium, 0.3 g nitrogen compounds mixed with 2 mL 40% glucose and filter sterilized, and bring to 50 mL with Trp-Leu- medium. Added ~8 mL to each small plate, making a total of 6 plates. | ||
+ | |||
+ | Lids going to be of equal size to plate. | ||
+ | |||
+ | IPTG induce 300 mL of culture for 5 hours because observed significan increase in bioluminescence when allowed to induce for 5 hours as opposed to 3 in failed Experiment 4. | ||
+ | |||
+ | Bacteria to Yeast Communication in Liquid Media: Experiment 1 | ||
+ | |||
+ | Yeast placed in small test tube and sealed with sterile velvet stuffed in it. Small test tube placed in larger one containing bacteria+luciferin. Spike luciferin at regular intervals. | ||
+ | |||
+ | Note: Preparing Materials for Filter Lifts | ||
+ | |||
+ | Cut nitrocellulose and filters to the appropriate shapes. If using BioDot, clean apparatus, insert thick filter, and prewet with water. In case of biodot or plates, place a Whatman filter paper in a container: for a plate a petri dish, for biodot, a 200 uL tip box lid. | ||
+ | |||
+ | Preparation of Beta Gal solution: in 20 mL of Z buffer, add 54 uL of beta mercaptoethanol, and 1 mg/mL of Beta gal dissolved in DMF. I diluted the Beta Gal in DMF at 50 mg per 500 uL, and added then 200 uL to the solution. | ||
+ | </p> | ||
<h3> Week 9: 8/3/09 - 8/7/09 </h3> | <h3> Week 9: 8/3/09 - 8/7/09 </h3> | ||
- | <p> | + | <p> Characterization of the Two Hybrid System |
+ | |||
+ | Laser Stimulation on Plates | ||
+ | |||
+ | Light was shone from a 660 nm laser on five points on the below plates for 10 seconds per point, with four points on the outside and a point in the center forming a cross. There is diffuse blue on the PCB+light plate and no blue on the control plates, indicating a positive result for light induced production of beta-gal. | ||
+ | |||
+ | Your browser may not support display of this image. | ||
+ | |||
+ | |||
+ | Qtip Assay | ||
+ | |||
+ | Take 1—Testing length of exposure of cells to light. </p> | ||
<h3> Week 10: 8/10/09 - 8/14/09 </h3> | <h3> Week 10: 8/10/09 - 8/14/09 </h3> | ||
- | <p> | + | <p> BioDot Characterization Assays |
+ | |||
+ | Biodot Assay I: Exposure time and Time to develop | ||
+ | |||
+ | Cells were exposed for sweep, 1 sec, and 10 sec, , in three replicates, one for each timepoint of ½ hour, 1 hr, 3 hours. I did this with oliver. After half an hour and 1 hours we loaded samples onto the biodot and did X gal assay. We did not do third timepoint due to apparent extremely high background from PCB. This turned out to fade over time. The fourth column on each filter is a DMSO only control, shone for 10 seconds. These cells were taken from relatively new cultures during week 8. This assay worked to show that (1) there is more apparent signal at 1 hour than half an hour, and (2) the longer the exposure (up to 10 seconds) the bright the signal, and (3) the DMSO only control does not cause xgal assay to turn blue, thus making false positives attributable to cell age. | ||
+ | |||
+ | Your browser may not support display of this image. | ||
+ | |||
+ | |||
+ | PCB Concentrations | ||
+ | |||
+ | 2 plates. 2 rows equivalent, two different tubes, were 0 PCB, 0 DMSO. Cells grown overnight. 1 ML cells from culture, spun down at 8,000 rpm, pelleted and took out medium, washed, re-suspended in synthetic Trp-Leu-medium, and resuspended in 1ml. So 1 mL of culture from 2mL of culture originally incolutated at 10 pm last night. Took OD600 reading diluted at 1:10. DMSO makes the cells clump so you really have to vortex and shake them. Too much DMSO inhibits their growth, and PCB up to high concentrations does not seem to inhibit it. Need to multiply all number by 10. Not in triplicate, probably +- 0.05. Need to be consistant about shaking up REALLY well. You will be significantly off otherwise. | ||
+ | |||
+ | PCB DMSO Equivalents | ||
+ | |||
+ | 0 uMol .607 .586 | ||
+ | |||
+ | 5 .583 .518 | ||
+ | |||
+ | 10 .599 .533 | ||
+ | |||
+ | 25 .552 .452 | ||
+ | |||
+ | 50 .592 .432 | ||
+ | |||
+ | 100 .373 .316 | ||
+ | |||
+ | 125 .260 .175 | ||
+ | |||
+ | The decrease in growth is apparently a function of DMSO concentration, not PCB, since it is seen with both. | ||
+ | |||
+ | Did a 1:10 dilution of everything. when you zapped with laser, each had 100 uL aliquots of cells. All numbers below .607, everything was brought up to .6 OD worth of cells, should be 1x10^7 cells per mL, and 100 uL of cells. Then the plates were staggered—on one plate you have 2 rows of cells with no PCB no DMSO. In second plate they were staggered. First had 5 uMol DMSO, 5 mMol PCB, etc. Each got 10 seconds. Now sitting in incubator, finished at 8pm, going to go till 11, then transfer onto filters. | ||
+ | |||
+ | Cells were loaded into the biodot as follows, and two replicates of this were made (for a total of 8 samples per condition between the two films). Cells were loaded onto the nitrocellulose three hours after exposure. Labelled photographs PCB Concentrations I, II, and III. | ||
+ | 5 uM PCB 10 uM PCB 25 uM PCB 50 uM PCB 100 mM PCB 125 mM PCB | ||
+ | 5 uM PCB 10 uM PCB 25 uM PCB 50 uM PCB 100 mM PCB 125 mM PCB | ||
+ | 5 uM PCB 10 uM PCB 25 uM PCB 50 uM PCB 100 mM PCB 125 mM PCB | ||
+ | 5 uM PCB 10 uM PCB 25 uM PCB 50 uM PCB 100 mM PCB 125 mM PCB | ||
+ | 5 uM DMSO 10 uM DMSO 25 uM DMSO 50 uM DMSO 100 uM DMSO 125 uM DMSO | ||
+ | 5 uM DMSO 10 uM DMSO 25 uM DMSO 50 uM DMSO 100 uM DMSO 125 uM DMSO | ||
+ | 5 uM DMSO 10 uM DMSO 25 uM DMSO 50 uM DMSO 100 uM DMSO 125 uM DMSO | ||
+ | 5 uM DMSO 10 uM DMSO 25 uM DMSO 50 uM DMSO 100 uM DMSO 125 uM DMSO | ||
+ | |||
+ | No light no DMSO control No light no DMSO control | ||
+ | No light no DMSO control No light no DMSO control | ||
+ | No light no DMSO control No light no DMSO control | ||
+ | No light no DMSO control No light no DMSO control | ||
+ | No light no DMSO control No light no DMSO control | ||
+ | No light no DMSO control No light no DMSO control | ||
+ | No light no DMSO control No light no DMSO control | ||
+ | No light no DMSO control No light no DMSO control | ||
+ | |||
+ | Your browser may not support display of this image. Your browser may not support display of this image. Your browser may not support display of this image. | ||
+ | |||
+ | Conclusions: The experiment did not work because the cells are too old. | ||
+ | |||
+ | Laser Time-course | ||
+ | |||
+ | Times: 0.5sec, 1 sec, 5 sec, 10 sec, 30 sec, 1 min. | ||
+ | |||
+ | (DMSO, PCB, DMSO, PCB, etc). Using 50 mMol concentration. Overnight culture diluted to 1:10, diluted at 6pm, now it is 8:40. Load entire 96 well plate. Instead of a sweep we should do 0.5 sec. We will put 100 uL in each well. Take another OD reading of that sample. Going to be between about 0.6 and 0.8 OD600 for each well. They have been sitting since 6pm in media with no PCB. Still should be a lot of cells with active PCB…cytoplasm gets split evenly? Do they get diffused out? We only need a few complexes to initiate beta gal expression. Will be staggered like other plate, one row DMSO, one row PCB. | ||
+ | |||
+ | Cells were loaded into the biodot as follows, and two replicates of this were made (for a total of 8 samples per condition between the two films). Cells were loaded onto the nitrocellulose three hours after exposure. Labelled photographs Timecourse I and II. | ||
+ | 0.5 sec +PCB 1 sec + PCB 5 sec + PCB 10 sec + PCB 30 sec + PCB 1 min + PCB | ||
+ | 0.5 sec +PCB 1 sec + PCB 5 sec + PCB 10 sec + PCB 30 sec + PCB 1 min + PCB | ||
+ | 0.5 sec +PCB 1 sec + PCB 5 sec + PCB 10 sec + PCB 30 sec + PCB 1 min + PCB | ||
+ | 0.5 sec +PCB 1 sec + PCB 5 sec + PCB 10 sec + PCB 30 sec + PCB 1 min + PCB | ||
+ | No light +PCB No light +PCB | ||
+ | No light +PCB No light +PCB | ||
+ | No light +PCB No light +PCB | ||
+ | No light +PCB No light +PCB | ||
+ | |||
+ | Your browser may not support display of this image. Your browser may not support display of this image. | ||
+ | |||
+ | This assay did not work, all lanes turned blue, even the ones without light treatment or ones without PCB. We think there might be a mutation in the strain which results in constitutive expression of beta gal, or a contamination with some fungus or bacterium that does. If it is bacterial contamination this may pose a problem for the co-culture assay. Hopefully not though. This assay will be repeated with a lower density of cells, cultured from a frozen stock. Meanwhile I am looking for additional strains that will work. | ||
+ | |||
+ | Per Oliver: | ||
+ | |||
+ | “So regarding the observation that the Y190 pif3/Phyb strains have a high background of B-gal expression when taken from either later cultures or an older plate VS. from the earlier frozen glycerol stocks. I have a hypothesis: There shouldn't be a selective advantage to any cells that have a "leaky" or mutated gal1 promoter driving B-gal, quite the contrary since they're growing in glucose, so it would be a waste of resources to crank out b-gal. However, the other reporter gene in this strain, which is also regulated by a Gal1 promoter is the HIS3 gene, which if turned on all of the time, will give cells a selective advantage if they're on media which is depleted of supplemented histidine, i.e. old overnight cultures, old plates, etc. Since B-gal is also turned on, maybe whats happening is that we are over time inadvertantly selecting for mutation(s) in either PhyB or Pif3 (and remember, there are multiple copies of these plasmids within each cell) that enable both proteins to bind constitutively now sans light ( or hell, maybe even sans PCB). | ||
+ | If this is correct, then then any Gal1 promoter regulated gene would be constitutively on in such a strain. We can test this hypothesis, if we choose to later, to see if HIS3 is also up regulated and also if Pif3/PhyB are now bound sans light in a pull down assay, and whether those Pif3/PhyB plasmids have a particular point mutation that enable them to be constitutively bound. Also whether this mutation can crop up under other selective pressures, ie. growing the strain using galactose as the sole carbon source, for protracted periods of time. | ||
+ | So what does this mean practically, for the rest of the experiments, if correct? Well, we should make lots of FRESH overnight cultures directly from our frozen stocks, making sure that the media has extra histidine supplemented, and freeze those down. Make more preps of the PhyB and Pif3 plasmids that are working. Consider putting those into another strain (Y187) that does not have a gal1 promoter driven marker that would offer a selective advantage when kept turned on. Keep all of this in mind when we're making the stable transformants, maybe we'll have to generate those first and then put the plasmids back in (either Y190 or Y187). | ||
+ | I haven't done any literature searches yet to see if this can likely occur in the context of a 2-hybrid system or if this effect has been already observed in other regulated selectable marker systems that offer a metabolic/nutritional advantage. But it makes sense to me if you consider that 5-FOA is used as a negative selection compound to screen for randomly arising URA3 point mutants.</p> | ||
</td> | </td> | ||
</tr> | </tr> | ||
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<li><a href="https://2009.igem.org/Team:Harvard/PCB">PCB Biosynthesis in Yeast</a></li> | <li><a href="https://2009.igem.org/Team:Harvard/PCB">PCB Biosynthesis in Yeast</a></li> | ||
<li><a href="https://2009.igem.org/Team:Harvard/Split">Split Luciferase</a></li> | <li><a href="https://2009.igem.org/Team:Harvard/Split">Split Luciferase</a></li> | ||
- | <li><a href="https://2009.igem.org/Team:Harvard/Blackboard"> | + | <li><a href="https://2009.igem.org/Team:Harvard/Blackboard">Other Possible Reporters</a></li> |
- | + | ||
- | + | </ul> | |
<h2><p><a href="https://2009.igem.org/Team:Harvard/Parts">Parts</a></p></h2> | <h2><p><a href="https://2009.igem.org/Team:Harvard/Parts">Parts</a></p></h2> | ||
<h2><p><a href="https://2009.igem.org/Team:Harvard/References">References</a></p></h2> | <h2><p><a href="https://2009.igem.org/Team:Harvard/References">References</a></p></h2> | ||
Line 567: | Line 1,442: | ||
</ul> | </ul> | ||
<h2><p><a href="https://2009.igem.org/Team:Harvard/Ethics">Ethics</a></h2> | <h2><p><a href="https://2009.igem.org/Team:Harvard/Ethics">Ethics</a></h2> | ||
+ | <h2><p><a href="https://2009.igem.org/Team:Harvard/Safety">Safety</a></h2> | ||
+ | <h2><p><a href="https://2009.igem.org/Team:Harvard/Acknowledgements">Acknowledgements</a></h2> | ||
</td> | </td> | ||
</tr> | </tr> |
Latest revision as of 03:34, 22 October 2009
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