Difference between revisions of "20.109(F19):Treat cells for gamma-H2AX (Day2)"

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(Part 1: Treat cells for γH2AX assay)
(Introduction)
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[[Image:Fa16 M1D5 H2AX-P.png|thumb|center|500px|'''H2AX is phosphorylated in response to DNA double-strand breaks.''']]
 
[[Image:Fa16 M1D5 H2AX-P.png|thumb|center|500px|'''H2AX is phosphorylated in response to DNA double-strand breaks.''']]
  
In your γH2AX assay, you will assess the effects of exposure to MMS +/- As.  In addition to measuring double-strand breaks via γH2AX foci, you will also evaluate the health of the cells using  a cell proliferation assay.  The cell proliferation assay measures DNA synthesis as a measure of cell health.   
+
In your γH2AX assay, you will assess the effects of exposure to MMS +/- As.  In addition to measuring double-strand breaks via γH2AX foci, you will also evaluate the health of the cells and assess cell cycle stage using  a cell proliferation assay.  The cell proliferation assay measures DNA synthesis as a measure of cell health and cell cycle.   
  
The cell proliferation assay you will employ is a commercially available kit that uses a thymidine analog, 5-ethynyl-2'-deoxyuridine (EdU).  EdU is added to the cell culture and incorporated into newly synthesized DNA.  Then a fluorescent azide dye is attached to the incorporated EdU bases.  The addition of a fluorescent dye allows you to visualize / differentiate cells that are actively dividing.  This provides information concerning the health of the cells, and in our case will provide information on the toxicity of the treatments applied.
+
The cell proliferation assay you will employ is a commercially available kit that uses a thymidine analog, 5-ethynyl-2'-deoxyuridine (EdU).  EdU is added to the cell culture and incorporated into newly synthesized DNA.  Then a fluorescent azide dye is attached to the incorporated EdU bases.  The addition of a fluorescent dye allows you to visualize / differentiate cells that are actively dividing.  This provides information concerning the health of the cells, and in our case will provide information on the toxicity of the treatments applied as well as treatment effects that may be dependent on cell cycle.
  
 
[[Image:Fa19 20109 EdU schematic.png|thumb|center|500px| '''EdU is incorporated into newly synthesized DNA.''']]
 
[[Image:Fa19 20109 EdU schematic.png|thumb|center|500px| '''EdU is incorporated into newly synthesized DNA.''']]

Revision as of 19:19, 23 August 2019

20.109(F19): Laboratory Fundamentals of Biological Engineering

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Fall 2019 schedule        FYI        Assignments        Homework        Class data        Communication
       1. Measuring genomic instability        2. Modulating metabolism        3. Testing chemical probes              


Introduction

In eukaryotes, including humans, DNA is tightly wound around histone groups. H2AX is a member of the core group of histones that contributes to nucleosome formation and DNA structure. When a DNA double-strand break is introduced into the genome, the H2AX histones near the break are phosphorylated by the ATM kinase at residue Ser-139. Upon phosphorylation H2AX is referred to as gamma-H2AX. Given that only H2AX histones near the site of DNA damage are phosphorylated, γH2AX is a useful target when determining the abundance and location of double-strand breaks.

H2AX is phosphorylated in response to DNA double-strand breaks.

In your γH2AX assay, you will assess the effects of exposure to MMS +/- As. In addition to measuring double-strand breaks via γH2AX foci, you will also evaluate the health of the cells and assess cell cycle stage using a cell proliferation assay. The cell proliferation assay measures DNA synthesis as a measure of cell health and cell cycle.

The cell proliferation assay you will employ is a commercially available kit that uses a thymidine analog, 5-ethynyl-2'-deoxyuridine (EdU). EdU is added to the cell culture and incorporated into newly synthesized DNA. Then a fluorescent azide dye is attached to the incorporated EdU bases. The addition of a fluorescent dye allows you to visualize / differentiate cells that are actively dividing. This provides information concerning the health of the cells, and in our case will provide information on the toxicity of the treatments applied as well as treatment effects that may be dependent on cell cycle.

EdU is incorporated into newly synthesized DNA.

Protocols

Part 1: Treat cells for γH2AX assay

PLACEHOLDER

MMS treatment

  1. Calculate the dilution of MMS needed to have a final concentration of 0.4 mM.
    • MMS stock concentration is 12 mM.
    • You will need 1 mL of media for each well to be treated with MMS (see plate map to right).
  2. Upon entering the tissue culture room, ready your tissue culture hood with the supplies you will need to complete the experimental procedures.
  3. Prepare your MMS dilution according to the calculations you completed in Step #1.
  4. Retrieve the 12-well plate that you seeded in the previous laboratory session from the 37 °C incubator.
  5. After aspirating off the media in the wells, add 1 mL of fresh media or media + 0.4 mM MMS to the appropriate wells according to the plate map.
  6. Incubate at 37 °C for 1 hour.

Preparations for As treatment

  1. During the MMS treatment, calculate the dilutions of EdU and As needed to have final concentrations of 10 μM and 80 μM, respectively.
    • EdU stock concentration is 10 mM and As stock concentration is 100 mM.
    • You will dilute in a final volume of 1 mL of media / well.
  2. Next, make a plan for the As treatment! Remember from prelab that the EdU will be applied to all of the cultured cells in your plate for 30 min. In the conditions with As treatment, the media containing both EdU and As must be replaced with media containing only As after 30 min.
    • To organize yourself, complete the table below to assist you in calculating the volume of each component needed to treat the duplicate wells in each condition. For example, in Condition #1 you should generate a mix that contains, 2 μL EdU and 2 mL media for a final volume of 2 mL (1 mL is added to each duplicate well...because 2 μL is a negligible volume in this instance there is no need to account for it in the total volume of the mix).
    • Following the EdU incubation, the media in each well must be replaced with either media or media containing As. Create another table to assist you in preparing the mixes needed in this step of the procedure.
    • Check all calculations with the teaching faculty prior to completing the remaining steps!
Condition EdU (final concentration = 10 μM) As (final concentration = 80 μM) Media Final volume (1 mL / well)
No treatment control (no MMS, no As) 2 μL 0 2 mL 2 mL
MMS, no As
no MMS, As
MMS, As

As treatment

  1. With ~15 min remaining in the MMS treatment, prepare your mixes for the EdU +/- As incubation.
  2. Retrieve your 12-well plate from the incubator and use a pipette to remove the media from the wells, transferring the media containing As to the As waste container.
  3. Add each Edu +/- As mix to the appropriate wells according the plate map above and incubation at 37 °C for 30 min.
  4. Prepare your mixes for the +/- As treatment.
  5. Retrieve your 12-well plate from the incubator and use a pipette to remove the media from the wells, transferring the media containing As to the As waste container.
  6. Add each +/- As mix to the appropriate wells according the plate map above and incubation at 37 °C for 90 min.
  7. Following treatment, transfer media to the As waste container and immediately add 400 μL of 4% paraformaldehyde to fix the cells.
  8. Incubate at room temperature for 10 min.
  9. Collect the 4% paraformaldehyde in the correct waste stream using a P1000 pipet from Plate #1.
  10. Wash with 500 μL of 1X PBS.
    • Add 1X PBS then remove using a P1000 pipet. Collect the PBS in the correct waste stream.
    • Complete a total of 2 times. Leaving 1 mL of 1X PBS on the cells in the final wash.
  11. Leave all wells with 1 mL PBS, parafilm the sides and move the fixed plates into the 4 °C cooler.

Part 2: Prepare CometChip

  1. Obtain a sheet of gelbond film from the laboratory bench at the front of the room. The paper is protecting the hydrophilic side of the gelbond film.
    • Be sure to keep the paper associated with the gelbond film so you know which side is which.
  2. Also obtain a special permanent marker from the front bench (Secureline Marker II).
    • If you use a marker from your drawer the ink will wash off during a later step in the CometChip assay protocol.
  3. Use the ruler in your team drawer and the Secureline permanent marker to draw a 4.5 x 3.5 cm rectangle near the center on the hydrophobic side of the gelbond film. Label three rows--'A', 'B', and 'C'--along the outside of the long side of the rectangle.
    GelBond marking for CometChip
    • Note: you are writing on what will be the bottom of the CometChip and may want to write backwards so the labels are clear when you look at the top of your CometChip.
  4. Prepare 20 mL of 1% normal melting point (NMP) agarose. Be careful as the agarose solution will be very hot!
    • Calculate the amount of NMP agarose powder needed for a 1% w/v solution. Check your math with the teaching faculty before you continue.
    • Obtain a small milk bottle from the front bench.
    • Weigh out the appropriate amount of NMP agarose and add it to the milk bottle.
    • Use a cylinder to measure 20 mL of 1x PBS and add it to the milk bottle with the NMP agarose powder.
    • Swirl to mix.
    • To melt the NMP agarose, microwave the solution for 20 seconds, swirl, then microwave for 3-second intervals until all crystals are in solutions. After each interval, remove the milk bottle and gently swirl while checking for unmelted agarose crystals. It is important that the solution does NOT boil as you will lose water to evaporation and the density of the agarose will be altered. If your solution starts to boil, immediately remove it from the microwave and gently swirl.
    • When no more crystals are visible in the solution take the milk bottle to your bench.
  5. Obtain a small rectangle dish (labeled "scraped lid") and the CometChip 'stamp' from the front bench.
  6. Add 2.5 mL of the agarose solution to the small dish, then quickly place the gelbond film in the dish with the marked hydrophobic side down. Remove the paper from the film.
  7. Add 13 mL of the agarose solution on top of the gelbond film.
  8. Slowly place the CometChip stamp on top of the agarose.
    • Lower the bottom left of the stamp first, then slowly allow the stamp to 'roll' into the agarose. Be sure to leave the top right corner of the small dish accessible.
    • Be careful not to introduce bubbles into the agarose and work quickly as the agarose will solidify as it cools.
  9. Allow the agarose to solidify, undisturbed, on your bench for 30 min.
  10. Add ~5 mL of 1x PBS to the small dish that contains your agarose CometChip.
    • Pipet in the 1x PBS using the accessible corner.
  11. Slowly pull from one corner of the stamp to lift it away from your CometChip in the dish.
    • If the CometChip sticks to the stamp, carefully peel it off using tweezers.
    • Discard the PBS in the sink.
  12. Remove excess agarose from the perimeter of your CometChip using a razor blade (obtain and return razor blade to front bench).
  13. Clean the agarose from the bottom of your CometChip (gelbond side) using a Kimwipe.
  14. Place your CometChip in the small dish containing 1x PBS for storage at 4 °C until next time.
    • Be sure the chip is completely submerged.
  15. Please return the stamp to the front bench. Never wipe the stamp as that will ruin the microposts!

Reagents list

γH2AX

  • methyl methanosulfonate (MMS) (from Sigma)
  • arsenite (As) (from Sigma)
  • Click-iT EdU imaging kit (from Invitrogen)
    • 5-ethynyl-2'-deoxyuridine (EdU)

CometChip

  • agar, normal melting point (from Invitrogen)
  • phosphate buffered saline (PBS) (from VWR)
  • GelBond film (from Lonza)

Navigation links

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