Difference between revisions of "20.109(S23):M2D3"

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For timing reasons, two colonies from the spread plates you prepared in the previous laboratory session were inoculated into LB/Amp and grown overnight at 37°C on a rotator.
 
For timing reasons, two colonies from the spread plates you prepared in the previous laboratory session were inoculated into LB/Amp and grown overnight at 37°C on a rotator.
  
#Retrieve your two cultures from the font laboratory bench. Label two eppendorf tubes to reflect your samples (psgRNA_target#1 and psgRNA_target#2).  
+
#Retrieve your two cultures from the font laboratory bench. Label two eppendorf tubes to reflect your samples (Fet4_mutant#1 and Fet4_mutant#2).  
 
#Vortex the bacterial cultures and pour ~1.5 mL of each into the appropriate eppendorf tube. [[Image:Removing cells.jpg|thumb|right|200px|'''Diagram showing how to aspirate the supernatant.'''  Be careful to remove as few cells as possible.]]  
 
#Vortex the bacterial cultures and pour ~1.5 mL of each into the appropriate eppendorf tube. [[Image:Removing cells.jpg|thumb|right|200px|'''Diagram showing how to aspirate the supernatant.'''  Be careful to remove as few cells as possible.]]  
 
#Balance the tubes in the microfuge, spin them at maximum speed for 2 min, and remove the supernatants with the vacuum aspirator.
 
#Balance the tubes in the microfuge, spin them at maximum speed for 2 min, and remove the supernatants with the vacuum aspirator.

Revision as of 21:35, 1 February 2023

20.109(S23): Laboratory Fundamentals of Biological Engineering

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Spring 2023 schedule        FYI        Assignments        Homework        Class data        Communication        Accessibility

       M1: Drug discovery        M2: Protein engineering        M3: Project design       

Introduction

The CRISPRi system involves three genetic components: the pdCas9 plasmid (1 in image below), the psgRNA_target plasmid (2 in image below), and the targeted gene within the host genome (3 in image below). Though the targeted gene is native to the host genome, the plasmids must be transformed into the cell and maintained using antibiotic selection. Thus far in this module, we have discussed the CRISPRi plasmids as individual units, but now we will consider the system as a whole in the context of engineering gene expression.

Overview of CRISPRi system. The CRISPRi system consists of three genetic components: 1. an expression plasmid that encodes the pdCas9 protein that binds to DNA when complexed with sgRNA, 2. an expression plasmid that encodes the sgRNA that is complementary to the targeted sequence in the host genome, and 3. the targeted sequence in the host genome. Image generated using BioRender.

In the previous laboratory session, you performed the procedure used to generate the psgRNA_target plasmids. Today we will transform the CRISPRi system (pdCasd9 and psgRNA_target) is into E. coli. Once transformed into the bacterial cells, the sgRNA_target and dCas9 are transcribed from the respective expression plasmids. As an overview, the promoter (pJ23119) driving expression of the sgRNA sequence in the gRNA_target plasmid is constitutively active. This means that transcription of the gRNA sequence specific to the target in the host genome is constitutive. Therefore, your sgRNA_target is always present in the MG1655 cells. In a mechanism that we will discuss in the next laboratory session, expression of dCas9 is controlled using an inducer molecule.

Protocols

Part 1: Mini-prep pgRNA_target clones

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 a salt bridge between the silica and the DNA.

For timing reasons, two colonies from the spread plates you prepared in the previous laboratory session were inoculated into LB/Amp and grown overnight at 37°C on a rotator.

  1. Retrieve your two cultures from the font laboratory bench. Label two eppendorf tubes to reflect your samples (Fet4_mutant#1 and Fet4_mutant#2).
  2. Vortex the bacterial cultures and pour ~1.5 mL of each into the appropriate 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 each culture into the appropriate eppendorf tube (add the culture to the pellet previously collected), and repeat the spin step. Repeat until you use up the entire volume of culture.
  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. Transfer each column insert (blue) to the trimmed eppendorf tube you prepared (cut off lid).
  14. 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.
  15. Cap the trimmed tube or transfer elution to new eppendorf tube.
  16. Alert the Instructor when you are ready to measure the concentration of DNA in your mini-prep.

In your laboratory notebook, complete the following:

  • Record the concentration for each of the mini-prep you prepared.
  • Record the 260/280 ratio for of the mini-preps you prepared. What does this value indicate about the purity of the DNA in your mini-preps?

Part 2: Transform mutated plasmid into W303α yeast cells

Following DNA production by competent bacteria, the next step is moving the plasmid to our yeast model system for experimentation. To do this, we create competent W303α cells and use a proprietary chemical transformation procedure to insert our newly created mutations. Yeast that have successfully been transformed are selected by utilizing plates that are made with synthetic dropout media, allowing only yeast expressing our plasmid to survive.

During transformation, a plasmid enters a competent yeast, then replicates and expresses the encoded genes. In a co-transformation, the goal is to transform each bacterial cell with two plasmids that each encode a different set of genes. Following the transformation procedure, a mixed population of cells exists as shown in the figure to the right: some cells did not uptake the plasmid (gray cells) while others contain the plasmid that carries the cassette allowing for uracil production (purple cells), Because the agar plate used for selection does not contain a uracil supplement, only bacterial cells that harbor the plasmid survive and reproduce to form a colony.

Schematic of bacterial co-transformation. Yeast cells that harbor the plasmid (purple cells) are selected for using an agar plate that lacks uracil.
In the yeast plasmid system, a gene on the Fet4 expression plasmid encodes an ODCase cassette which catalyzes de novo synthesis of uracil. Thus, only transformed yeast will grow on agar plates lacking a uracil source.

Most yeast do not usually exist in a “transformation ready” state, referred to as competence. Instead yeast cells are incubated with LiAc to promote competency by making the cells permeable to plasmid DNA uptake. Competent cells are extremely fragile and should be handled gently, specifically the cells should be kept cold and not vortexed. The transformation procedure is efficient enough for most lab purposes, but much lower than bacterial transformation efficiency. Bacterial efficiencies can be as high as 109 transformed cells per microgram of DNA, while yeast transformation using lithium cations tends to peak at 106 transformed cells per microgram of DNA.

You will transform each of your mini-prepped Fet4 mutant plasmids into W303α yeast, which is the strain we will use to examine the effect of your approach on cadmium uptake.

  1. Label two 1.5 mL eppendorf tubes with your team information and clone designation (Fet4_mut#1 and Fet4_mut#2).
  2. Acquire an aliquot of the competent W303α yeast (prepared by the Instructors) from the front laboratory bench.
  3. Pipet 50 μL of the W303α competent cells into each labeled eppendorf tube.
    • Remember: it is important to keep the competent cells on ice! Also, avoid over pipetting and vortexing!
  4. Add 5 μL of each Fet4 mutant candidate clone mini-prep to the appropriate eppendorf tube.
  5. Add 500 μL Solution 3 and mix gently by flicking the tube.
  6. Incubate your transformation mixes at 30 °C for 45 min, gently mixing 2-3 times throughout the incubation.
  7. Once you have begun the incubation, retrieve and label one SD-U plate for each transformant. Be sure to include transformant number, your team/section, and the date on each plate.
  8. Retrieve your transformations from the incubator and alert the teaching faculty that you are ready to plate your samples.
  9. Plate 150μL of each co-transformation onto an appropriately labeled SD-U agar plate.
    • The teaching faculty will demonstrate how you should 'spread' your co-transformation onto the SD-U agar plates. You should include this procedure in your laboratory notebook.
  10. Incubate your spread plates in the 30 °C incubator for 2-4 days.

Part 3: Prepare Fet4 mutant clones for sequencing analysis

DNA sequencing will be used to confirm that the site-directed mutagenesis is correct. The invention of automated sequencing machines has made sequence determination a relatively fast and inexpensive process. The method for sequencing DNA is not new but automation of the process is recent, developed in conjunction with the massive genome sequencing efforts of the 1990s and 2000s. At the heart of sequencing reactions is chemistry worked out by Fred Sanger in the 1970s which uses dideoxynucleotides, or chain-terminating bases. These chain-terminating bases can be added to a growing chain of DNA but cannot be further extended. Performing four reactions, each with a different chain-terminating base, generates fragments of different lengths ending at G, A, T, or C. The fragments, once separated by size, reflect the DNA sequence due to the presence of fluorescent dyes, one color linked to each dideoxy-base. The four colored fragments can be passed through capillaries to a computer that can read the output and trace the color intensities detected.

Principles of Sanger sequencing. A. Chain-terminating bases are used to halt the DNA synthesis reaction at different lengths and attach a fluorophore that is used to determine the sequence of the DNA strand. B. The sequence of the DNA strand is determined using the fluorescent signature associated with each length of DNA in the reaction, this is visualized as a chromatogram.

Just as 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 kb in size. Though the target sequence for your point mutation is shorter than 1000 bp, we will sequence with both a forward and reverse primer to double-check that the sequence is correct (i.e. free of unwanted mutations).

The sequences for the primers you will use to confirm your Fet4_mutant insert are below:

Primer Sequence
Fet4 confirmation forward primer 5' - CGG TAC ATA CAC AGG TTT AAT TGG - 3'
Fet4 confirmation reverse primer 5' - CGT ACA AAG CGG TAA CCT CC - 3'

Because you will examine the Fet4 sequence in your using both a forward and a reverse primer, you will need to prepare two reactions for each mini-prep. Thus you will have a total of four sequencing reactions. For each reaction, combine the following reagents in a clearly labeled eppendorf tube:

  • 12 μL nuclease-free water
  • 8 μL of your plasmid DNA candidate
  • 10 μL of the primer stock from the front laboratory bench (the stock concentration is 5 pmol/μL)

In your laboratory notebook, complete the following:

  • Calculate the quantity (in ng) of DNA in each of the sequencing reactions.
  • Calculate the final concentration of sequencing primer in each reaction.

Reagents list

  • QIAprep Spin Miniprep Kit (from Qiagen)
    • buffer P1
    • buffer P2
    • buffer N3
    • buffer PB
    • buffer PE
  • Frozen-EZ Yeast Transformation II Kit (from Zymo Research)
    • Solution 3
  • Chemically competent W303α (genotype: MATa/MATα {leu2-3,112 trp1-1 can1-100 ura3-1 ade2-1 his3-11,15} [phi+])
  • SD-U plates
    • Synthetic dropout (SD) media: 0.17% yeast nitrogen base without amino acid and ammonium sulfate (BD Bacto), 0.5% ammonium sulfate (Sigma), 0.192 % amino acid mix lacking uracil (Sigma), 2% glucose (BD Bacto), 0.1% adenine hemisulfate (Sigma)
    • Plates prepared by adding 2% agar (BD Bacto) to SD media

Navigation links

Next day: Determine transporter mutation and prepare metal uptake experiment

Previous day: Perform site-directed mutagenesis