Team:BNDS China/Experiments

Experiments






Polymerase Chain Reaction (PCR)

We used Q5 DNA polymerase purchased form NEB for PCR. Below are the different groups and primers we used for amplifying gadR, gadC, gadA, and GFP insert sequences.

Bacterial Strains
Species Strains Description
Escherichia coli DH5α Cloning host
Escherichia coli Nissle Expression host
Plasmids
ID Antibiotic resistance Description
Repressor Generator (RPG) Ampicillin Cloning & Expression vector
RPG-LacI-Ptac-RBS-gadR-RBS-gadC-RBS-gadA-terminator Ampicillin Expression plasmid carrying LacI, gadR, gadC, gadA from Lactobacillus brevis NCL912 and pTac from original RPG
RPG-LacI-Ptac-B0034-gadA-B0034-E0040-terminator Ampicillin Expression plasmid carrying LacI, gadA from Lactobacillus brevis NCL912 and pTac from original RPG. With super ribosomal binding site before gadA and GFP (Green Fluorescent Protein), respectively.
RPG-LacI-Ptac-B0034-gadA-Linker-Histag-terminator Ampicillin Expression plasmid with Overexpression of gadA with super ribosomal binding side under the control of a lactose inducible promoter from Lactobacillus brevis NCL912 and intending to exam expression of gadA using integrated polyhistidine-tag.
LacI-Ptac-B0034-gadA-Linker-E0040-terminator Ampicillin Expression plasmid with Overexpression of gadA with super ribosomal bonding side controlling with lactose inducible promoter and intending to exam expression of gadA using integrated fluorescent protein.
Primers
Primer ID Sequences (5’ to 3’) Amplification Size (bp) Target Genes
ecRBS-1-gadR-F ACCATAGATAAGAGTTTAATCGCAGatggaatcaagaacgaaggacattct 644 gadR
ecRBS-1-gadR-R ccacTCTCTAATGTCCTCGCCGTGACGTttagacagataatacttgttgtttaaataa
ecRBS-1-gadC-F ACGTCACGGCGAGGACATTAGAGAgtggatgaaaataagtctggacagcagattgatac 1554 gadC
ecRBS-1-gadC-R TACCTGTTACCGTCGTAATGTGCGttacttagtttccttttccaatgattcatccg
ecRBS-13-gadA-F CGCACATTACGACGGTAACAGGTAatgactaaacaggatcaggaaacgca 1486 gadA
RPG-gadA-R ccattcgccattcaggttagttgtgaactgtcgtcttgttatcagtatccg
RPG-gadA-F gttcacaactaacctgaatggcgaatggtaaGGTCTC 4882 RPG vector for gadRCA
ecRBS-1-RPG-R ccatCTGCGATTAAACTCTTATCTATGGTATTATTTGTAGAGGCTGTTTCGTCCTCAC
ptac-gadA-F acaattaaagaggagaaatactagatgactaaacaggatcaggaaacgcag 1481 gadA
gadA-GFP-R CCACCGCCACCttagttgtgaactgtcgtcttgttatcagtatccg
gadA-GFP-F cacaactaaGGTGGCGGTGGCtctatgcgtaaaggagaagaacttttcact 1043 GFP
GFP-RPG-R ttgatgcctggACTAGTAGttattatttgtatagttcatccatgccatgtgtaatcc
RPG-GFP-F taaCTACTAGTccaggcatcaaataaaacgaaaggctca 4847 RPG for old GFP construction
ptac-gadA-R ctagtatttctcctctttaattgtgagcgctcacaattccacaca
gadA-RPG-F ctCATCATCATCATCATCACtaaCTACTAGTccaggcatcaaataaaacgaaaggctca 4791 RPG for His-tag construction
ptac-gadA-R ctagtatttctcctctttaattgtgagcgctcacaattccacaca
ptac-gadA-F acaattaaagaggagaaatactagatgactaaacaggatcaggaaacgcag 1500 gadA
gadA-RPG-R gTGATGATGATGATGATGagaGCCACCGCCACCgttgtgaactgtcgtcttgttatcagtatccg
Q5 PCR Reaction system (50 μL) for gadR/gadC/gadA/GFP:
  1. Q5 Reaction Buffer (5x): 10 μL
  2. dNTP: 1 μL
  3. Forward Primer/ Reverse Primer :2.5 μL/2.5 μL
  4. Template: 45ng
  5. Q5 DNA Polymerase: 0.5 μL
  6. ddh2O:33 μL
Q5 PCR Reaction system (50 μL) for the vector RPG
  1. Q5 Reaction Buffer (5x): 10 μL
  2. dNTP: 3 μL
  3. Forward Primer/ Reverse Primer :2.5 μL/2.5 μL
  4. Template (RPG): 45ng
  5. Q5 DNA Polymerase: 0.5 μL
  6. ddh2O:31 μL



Gibson Assembly

Since we had many segments, the success rate for Gibson assembly of 4 segments directly would be relatively low. Hence we chose to run Gibson Assembly twice. First, we conducted Gibson Assembly toward two groups of two segments. Then, we mixed the two Gibson Assembly reaction systems together.

Group Assembly 1 Assembly 2
RPG-gadR-gadC-gadA RPG for RCA and gadR gadC and gadA
RPG-A-GFP (old) RPG for GFP (old) gadA and GFP
RPG-A-linker-His tag RPG and gadA with His-tag N/A
RPG-A-linker-GFP RPG-1 and GFP RPG-2 and gadA



Gibson Products Transformation

We transformed our Gibson products into competent E. coli DH5α cells.

Transformation system:

Positive control: 25 μL competent cell + 1 μL RPG

Negative control: 25 μL competent cell

Experiment group (with Gibson products): 50 μL competent cells + 2 μL Gibson products




Colony PCR

Gibson Assembly might cause a relatively high probability of false positive. In order to check whether the colony incorporated the targeted plasmid we expected, we ran colony PCR and used UV gel imaging to observe PCR product bands and then ran sequencing.

  1. Pick 6-10 colonies.
  2. Add 20 μL Amp+ liquid LB broth into 0.2 mL microfuge tube and add colonies, respectively. Then use 37°C shaker (with rotate speed 270r/min) to revive the bacteria for 1 hour.
Colony PCR Reaction System:
  1. Taq Mix: 12.5 μL
  2. Forward Primer/ Reverse Primer: 1 μL/1 μL
  3. Bacteria LB solution: 2 μL
  4. ddh2O: 10.5 μL



Plasmid Extraction

As the sequencing results were confirmed after comparing with the constructed plasmid, we in vitro cultured E. coli for 12 hours, then used the protocol of Axygen Mini-prepare Plasmid Extraction Kit to extract the RPG-gadR-gadC-gadA plasmid.




Plasmid Transformation

Since E. coli Nissle 1917 was not a conventionally used strain for synthetic biology, we decided to transform the desired plasmid instead of Gibson products into E. coli Nissle.




IPTG Induction for the First and Second Construction

We used the overnight (12 hours) incubated bacteria LB solution, diluted them 200x into Amp+ LB/M9 with 0.5 mM and 1mM IPTG, MSG (our substrate: sodium glutamate, 6 mL system), then we incubated them for 3 hours. After the incubation of 3 hours, E. coli Nissle 1917 would reach the early point of its exponential growth period. We then diluted the bacteria solution again 200x into Amp+ LB/M9 with 0.5 mM and 1mM IPTG, MSG(6 mL system) respectively and incubated 12 hours.




IPTG Induction for the Third Construction

The system and procedures were similar to that of IPTG Induction for the First and Second construction, instead we used only a concentration of 1mM IPTG to induce bacteria. And since we planned to do the reaction between MSG and GAD outside our bacteria, we did not add MSG through the induction process. We used incubation shaker to incubate two 5mL bacteria LB solution for 8 hours and we transform the solution to 1L A+ LB solution. Then we incubated the bacteria for another 3 hours in order to allow bacteria entering exponential growth stage. Eventually, we added IPTG with the final concentration of 1mM and induced overnight.




Plate Reader Measurement for GFP Constructions

We measured the concentration of GFP using a Plate Reader to estimate the expression of gadA.




Protein treatment for the first construction

We first added lysis buffer (pH=7.8) and PMSF (Phenylmethanesulfonyl fluoride) protease inhibitor to avoid enzymes in lysosome degrading our target protein - GAD enzyme. Then we used ultrasound cell disrupter to lyse our bacteria. After that, we ran SDS-PAGE to observe generally if there were correct protein bands at 55 kDa (The length of GAD is 54.8).




Protein treatment for the second construction

We did not treat the induced bacteria solution, and we measured GABA directly. (See details in “GABA Measurement”)




Protein Purification for the third construction 1.1 (His-tag)

We first added lysis buffer (0.2M Sodium acetate-Acetic acid Buffer, pH=4.6) and PMSF (Phenylmethanesulfonyl fluoride) protease inhibitor to avoid enzymes in lysosome degrading our target protein --- GAD enzyme. Then we used ultrasound cell disrupter to lyse our bacteria. After that, we suspend the bacteria solution on the nickel column, which would allow proteins to suspend on the column but not other molecules due to the 6x His tag we have added after gad A. Then we used imidazole to undergo competitive elution in order to elute our protein. After that, we used G250 (A type of Coomassie brilliant blue) to test whether the protein had been suspended on the column. At last, we ran SDS-PAGE to observe generally if there were correct protein bands at 55 kDa (The length of GAD is 54.8).




GAD enzyme Extraction for the third construction 1.2 (His-tag)

We have found another cofactor of the reaction of MSG and GAD --- Vitamin B, and direct protein purification process will eliminate not only gab T (see wiki-demonstration and project description) but also the cofactor Vitamin B. Meanwhile, the direct enzyme extraction will stop TCA cycle and the function of gab T which might influence the existence of GABA. So, we first added PMSF and then we used ultrasound (20 min, P=200W) to lyse bacteria directly and use the enzyme extraction solution to react with MSG directly.




The Reaction of the Third Construction 1.1

According to the result derived from our mathematic model, we prepared 3 acetic acid-sodium acetate buffers with pH=4.2, 4.4, 4.6 respectively. Then we added 2% MSG into the buffer and 800 μg GAD solution into the reaction system (20mL). After that, we incubated the reaction system with 100r/min and 37°C shaker for 3 hours.




GABA Measurement for the first and second construction

We measured the induced bacteria LB solution directly via AAA (Amino Acid Analyzer). Before the measurement, we ran the GABA standard curve with pure GABA (concentration of 50, 100ppm and 200ppm, filtered before adding samples). After that, we used the ultrasound with ice to lyse the bacteria, then centrifuged products for 10 minutes with 4 °C. We diluted samples and transferred the solutions into the vial afterward.




GABA Measurement for the third construction

We measured the induced bacteria LB solution directly via AAA (Amino Acid Analyzer). Before the measurement, we ran the GABA standard curve with pure GABA (concentration of 50, 100ppm and 200ppm, filtered before adding samples). Meanwhile, we diluted all our samples 12x with ddh2O and filter with 0.2 nm filter membrane.

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