20.109(S16):Prepare expression system (Day4)

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20.109(S16): Laboratory Fundamentals of Biological Engineering

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Introduction

Now that you have prepared DNA encoding your mutant inverse pericams, we need to produce the proteins so we can assess the affinity and cooperativity of your new protein. Since the last time you were here, your oh-so devoted teaching staff transformed competent bacteria (strain NEB 5α) with your SDM product. Successfully transformed NEB 5α bacteria grew into colonies on ampicillin-containing plates, and two colonies were picked to grow in liquid cultures. The liquid culture of E. coli serves as a plasmid-generating factory. Today you will purify the plasmids carrying the hopefully mutated inverse pericam gene using a Qiagen mini-prep kit. To ensure that the SDM reaction was successful, and therefore the IPC gene was mutated, you will prepare the purified DNA for sequencing analysis. Though the NEB 5α cell strain is able to replicate the inverse pericam plasmid DNA, it cannot produce the inverse pericam protein. Therefore, you will transform your IPC mutant plasmids into a new bacterial system, BL21(DE3)pLysS, that can produce the protein for later analysis.

Vector map of pRSET modified from Invitrogen manual.

The bacterial expression vector we are using, pRSET, encodes many features that make it ideal for our research purposes. To enable selection of bacterial cells that carry the plasmid, an antibiotic cassette (specifically, an ampicillin marker) is included on the vector. Several features are included to promote protein expression and purification. In the image to the right a schematic representation of these features is shown. The T7 promoter drives expression of the gene that encodes IPC (or your mutated IPC). To ensure that the transcript is translated into a protein, a Ribosome Binding Site (RBS) is included. The ATG sequence serves as the transcriptional start and the 6xHis represents the six-histidine residue tag that is used for protein purification via affinity chromatography.

As mentioned above, pRSET encodes the bacteriophage T7 promoter, which is active only in the presence of T7 RNA polymerase (T7RNAP), an enzyme that therefore must be expressed by the bacterial strain used to make the protein of interest. We will use the BL21(DE3)pLysS strain, which has the following genotype: F-, ompT hsdSB (rB- mB-) gal dcm (DE3) pLysS (CamR). In BL21(DE3), T7RNAP is associated with a lac construct. Constitutively expressed lac repressor (lacI gene) blocks expression from the lac promoter; thus, the polymerase will not be produced except in the presence of repressor-binding lactose or a small-molecule lactose analogue such as IPTG (isopropyl β-D-thiogalactoside). To reduce ‘leaky’ expression of the protein of interest (in our case, inverse pericam), the pLysS version of BL21(DE3) contains T7 lysozyme, which inhibits basal transcription of T7RNAP. This gene is retained by chloramphenicol selection, while the pRSET plasmid itself (and thus inverse pericam) is retained by ampicillin selection.

Overview of protein expression system.


After completing mini-preps to isolate your plasmid DNA today (two mutant pRSET-IPC candidates), you will prepare the DNA for sequencing analysis, as well as use it immediately for transformation. In order to transform BL21(DE3)pLysS cells with your mutant IPC plasmids, you will first have to make the cells competent, i.e., able to efficiently take up foreign DNA. With the NEB 5α strain, we used commercially available competent cells that did not need further treatment prior to DNA addition. Today, you will make chemically competent cells yourself using calcium chloride, then incubate them with plasmid DNA and heat shock them as before prior to plating. Whether prepared by a company or by you, remember that competent cells are extremely fragile and should be handled gently, i.e. kept cold and not vortexed. Bacterial transformation is efficient enough for most lab purposes, resulting in as many as 109 transformed cells per microgram of DNA, but even with highly competent cells only 1 DNA molecule in about 10,000 is successfully transformed.

After today's lab session, the teaching staff will pick colonies and set up liquid overnight cultures from your transformed BL21(DE3)pLysS cells. Next time, you will add IPTG to these liquid cultures to induce expression of your mutant proteins, which you will then isolate and characterize.

Protocols

Part 1: Prepare competent BL21(DE3)pLysS cells

  1. Pick up one 5 mL tube of BL21(DE3)pLysS cells. These cells should be in or near the early- or mid-log phase of growth, which is indicated by an OD600 value of 0.4-0.8.
  2. Measure the OD600 value of a 1:10 dilution of your cells (use a total volume of 650-700 μL). If the cells are not yet dense enough, return them to the rotary shaker in the incubator. Remember to balance with another tube! As a rule, your cells should double every 20-30 minutes.
  3. Once your cells have reached the appropriate growth phase, aliquot them into 3 eppendorf tubes each containing 1.5 mL culture volume. Spin for 1 min at max speed (~16,000 rcf/13,000 rpm), aspirate the supernatants, and resuspend in 1.5 mL of ice-cold calcium chloride (100 mM). Note: you can balance these tubes in the centrifuge with three-way symmetry.
    • You may find it easiest to resuspend the cells in a small volume first (say, 200 μL), then add the remaining volume of CaCl2 (e.g., in two steps of 650 μL) and invert the tubes to mix.
  4. Spin again for 1 min. The resultant pellets should occur as streaks down the side of the eppendorf tube, so be very careful not to disturb the cells when aspirating.
  5. This time, resuspend each pellet in 100 μL of CaCl2, then pool the cells together in one tube.
    • Alternatively, resuspend the first pellet in 300 μL, then use this cell solution to resuspend the next pellet, and the next.
  6. Incubate on ice for 1 h. You can work on Parts 2, 3 and 5 of today's protocols now, as well as assemble the materials for Part 4. Among other things, be sure to label four eppendorfs and pre-chill them on ice. The labels should indicate a (-) no DNA control, a (+) wild-type IPC transformation control (with minipreps prepared and vetted by the teaching staff), and your two mutant candidate transformations (X#Z -1 and -2).

Part 2: Mini-prep pRSET-IPC X#Z

The procedure for DNA isolation using small volumes is commonly termed "mini-prep," which distinguishes it from a “maxi-prep” that involves a larger volume of cells and additional steps of purification. The overall goal of each prep is the same -- to separate the plasmid DNA from the chromosomal DNA and cellular debris. In the traditional mini-prep protocol, the media is removed from the cells by centrifugation. The cells are resuspended in a solution that contains Tris to buffer the cells and EDTA to bind divalent cations in the lipid bilayer, thereby weakening the cell envelope. A solution of sodium hydroxide and sodium dodecyl sulfate (SDS) is then added. The base denatures the DNA, both chromosomal and plasmid, while the detergent dissolves the cellular proteins and lipids. The pH of the solution is returned to neutral by adding a mixture of acetic acid and potassium acetate. At neutral pH the SDS precipitates from solution, carrying with it the dissolved proteins and lipids. In addition, the DNA strands renature at neutral pH. The chromosomal DNA, which is much longer than the plasmid DNA, renatures as a tangle that gets trapped in the SDS precipitate. The plasmid DNA renatures normally and stays in solution. Thus plasmid DNA got effectively separated from chromosomal DNA and proteins and lipids of the cell.

Today you will use a kit that relies on a column to collect the renatured plasmid DNA. The silica gel column interacts with the DNA while allowing contaminants to pass through the column. This interaction is aided by chaotropic salts and ethanol, which are added in the buffers. The ethanol dehydrates the DNA backbone allowing the chaotropic salts to form salt bridge between the silica and the DNA.

  1. Pick up your two cultures, which are growing in test tubes labeled with your team color. Label two eppendorf tubes to reflect your samples (X#Z 1 and 2).
  2. Vortex the bacteria and pour ~1.5 mL of each candidate into an eppendorf tube.
    Diagram showing how to aspirate the supernatant. Be careful to remove as few cells as possible.
  3. Balance the tubes in the microfuge, spin them at maximum speed for 2 min, and remove the supernatants with the vacuum aspirator.
  4. Pour another 1.5 mL of culture onto the pellet, and repeat the spin step.
  5. Resuspend each cell pellet in 250 μL buffer P1.
    • Buffer P1 contains RNase so that we collect only our nucleic acid of interest, DNA.
  6. Add 250 μL of buffer P2 to each tube, and mix by inversion until the suspension is homogeneous. About 4-6 inversions of the tube should suffice. You may incubate here for up to 5 minutes, but not more.
    • Buffer P2 contains sodium hydroxide for lysing.
  7. Add 350 μL buffer N3 to each tube, and mix immediately by inversion (4-10 times).
    • Buffer N3 contains acetic acid, which will cause the chromosomal DNA to messily precipitate; the faster you invert, the more homogeneous the precipitation will be.
    • Buffer N3 also contains a chaotropic salt in preparation for the silica column purification.
  8. Centrifuge for 10 minutes at maximum speed. Note that you will be saving the supernatant after this step.
    • Meanwhile, prepare 2 labeled QIAprep columns, one for each candidate clone, and 2 trimmed eppendorf tubes for the final elution step.
  9. Transfer the entire supernatant to the column and centrifuge for 1 min. Discard the eluant into a tube labeled 'Qiagen waste'.
  10. Add 0.5 mL PB to each column, then spin for 1 min and discard the eluant into the Qiagen waste tube.
  11. Next wash with 0.75 mL PE, with a 1 min spin step as usual. Discard the ethanol in the Qiagen waste tube.
  12. After removing the PE, spin the mostly dry column for 1 more minute.
    • It is important to remove all traces of ethanol, as they may interfere with subsequent work with the DNA.
  13. Add 30 μL of distilled H2O pH ~8 to the top center of the column, wait 1 min, and then spin 1 min to collect your DNA.

Part 3: Prepare DNA for sequencing reactions

Just like amplification reactions require a primer for initiation, primers are also needed for sequencing reactions. Legible readout of the gene typically begins about 40-50 bp downstream of the primer site, and continues for ~1000 bp at most. Thus, multiple primers must be used to fully view genes > 1 kbp in size. How many basepairs long is inverse pericam? Luckily, we only care about the back end of IPC, i.e. the part containing calmodulin, and therefore only need two primers to confirm our mutations: one primer will sequence in the forward direction and the second in the reverse direction to ensure complete coverage of the CaM gene.

The primers you will use today are below:

Primer Sequence (5' - 3')
IPC_F GTC CAG GAG CGC ACC ATC TTC
IPC_R GGC CCC AAG GGG TTA TGC

Use your APE file of IPC from M1D1 to determine where these primers anneal within the sequence. How many basepairs upstream and downstream of CaM do IPC_F and IPC_R, respectively, anneal?

The recommended composition of sequencing reactions is ~800 ng of plasmid DNA and 25 pmoles of sequencing primer in a final volume of 15 μL. The miniprep'd plasmid should have ~300 ng of nucleic acid/μL but that will be a mixture of RNA and DNA, so we will estimate the amount appropriate for our reactions.

Because you will examine the sequence of your potential mutants with both the IPC_F and IPC_R primers, you will need to prepare two reactions for each candidate. Thus you will have a total of four sequencing reactions. For each reaction, combine the following reagents directly in the appropriate tube within the 8-PCR-tube strip, as noted in the table below:

  • 6 μL nuclease-free water
  • 4 μL of your plasmid DNA candidate
  • 5 μL of the primer stock on the teaching bench (the stock concentration is 5 pmol / μL)
    • Please add the forward primer to the odd numbered tubes and the reverse primer to the even numbered tubes (i.e. tube #1 contains mutant #1 plasmid DNA and IPC_F primer, tube #2 contains mutant #1 plasmid DNA and IPC_R primer, etc).

The side of each tube is numerically labeled and you should use only the four tubes assigned to your group. The teaching faculty will turn in the strips at the Genewiz company drop-off box for sequencing.

T/R Tubes W/F
Red 1-4 Red
Orange 5-8 Orange
Yellow 9-12 Blue
Green 13-16 Pink
Blue 17-20 Purple
Pink 21-24
Purple 25-28

Part 4: Transform BL21(DE3)pLysS with pRSET-IPC X#Z

  1. Prewarm and dry 4 LB+Amp+Cam plates by placing them in the 37 °C incubator, media side up with the lids ajar. You will perform one transformation for each of your four samples (1 wild-type IPC, 2 mutants, and 1 no-DNA negative-control transformation).
  2. When your competent cells are ready, aliquot 70 μL of cells per pre-chilled eppendorf.
  3. Add 2 μL of the appropriate DNA to each tube. Remember, you are testing plasmid DNA that was prepared from two different colonies for your X#Z mutant, along with DNA from a colony that amplified the pRSET-IPC wild type. You will also perform a no DNA control.
  4. Flick to mix the contents and leave the tubes on ice for at least 5 min.
  5. Heat shock the cells on the 42 °C heat block for 90 s exactly and then put on ice for 2 min.
  6. Move the samples to a rack on your bench, add 0.5 mL of LB media to each one, and invert each tube to mix.
  7. Incubate the tubes in the 37 °C incubator for at least 30 min. This gives the antibiotic-resistance genes some time to be expressed in the transformed bacterial cells.
  8. While you are waiting, label 3 large glass test tubes with your team color and sample names.
    • Mix 10 mL LB broth with ampicillin and chloramphenicol, for final antibiotics concentrations of 100 ug/mL and 34 ug/mL, respectively. Aliquot 3 mL of this mixture per culture tube.
    • The teaching faculty will use these tubes to inoculate your colonies.
  9. Also prepare 4 eppendorf tubes containing 180 μL of LB each. You will use these to dilute your transformed cells 1:10 when you retrieve them from the incubator.
    • If you label these tubes with stickers rather than directly on the cap, you can then transfer each sticker to the appropriate plate as you go, saving one labeling step.
    • Note that we are reducing the cell concentration because miniprep DNA is much more concentrated than the DNA resulting from mutagenesis; it also does not require repair, further increasing the transformation efficiency.
  10. Plate 200 μL of each (1:10 diluted) transformation mix on a LB+Amp+Cam plate.
    • Safety reminder: After dipping the glass spreader in the ethanol jar, then pass it through the flame of the alcohol burner just long enough to ignite the ethanol. After letting the ethanol burn off, the spreader may still be very hot, and it is advisable to tap it gently on a portion of the agar plate without cells in order to equilibrate it with the agar.
  11. Once the plates are done, wrap them with colored tape and incubate them in the 37 °C incubator overnight. One of the teaching faculty will remove them from the incubator and set up liquid cultures for you to use next time.

Part 5: Count mutant colonies

When you have a spare moment today, count the colonies that arose on the NEB 5α cells transformed by the teaching faculty for your team, as well as on the positive and negative control plates. Does the negative control have any colonies? How does your mutation efficiency compare to that of the positive control? Please put your colony counts on today's Discussion page.

Reagent list

  • QIAprep Spin Miniprep Kit reagents
  • Sequencing primers (concentration = 5 pmol/μL)
  • 100 mM CaCl2, sterile
  • LB (Luria-Bertani broth)
    • 1% Tryptone
    • 0.5% Yeast Extract
    • 1% NaCl
    • autoclaved for sterility
  • Ampicillin stock: 100 mg/mL, aqueous, sterile-filtered, store at +4 °C
  • Chloramphenicol stock: 34 mg/mL in ethanol, store at -20 °C
  • LB+AMP+CAM plates
    • LB with 1.5% agar and 100 μg/mL ampicillin and 34 μg/mL chloramphenicol

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