Caspases,Paracaspases, and Metacaspases Methods and Protocols

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  1. Choose a working protein concentration of around 5–10 μg/
    mL or an optimized concentration from an earlier activity assay.

  2. Dilute the protein into 2× Assay Buffer to a fi nal concentration
    of 2× the chosen working concentration (~10–20 μg/mL).

  3. Place a 96-well black-bottomed plate on ice.

  4. Add 100 μL ddH 2 O to 11 wells on single row (wells 1–11) of
    the plate.

  5. In well 12 add 200 μL of substrate, diluted to 200 μM in
    ddH 2 O.

  6. Using a pipette, remove 100 μL of the solution in well 12 and
    place into the adjacent well (well 11). Mix by gently pipetting.

  7. Repeat this 2-fold (1/2) dilution (transferring 100 μL from
    well 11 to well 10 and so on) for all remaining wells.

  8. Discard 100 μL of the diluted substrate in well 1, leaving
    100 μL substrate in each well.

  9. Keeping the plate on ice, add 100 μL of the 2× protein–buffer
    mixture to each well.

  10. Remove the plate from the ice, place in the fl uorescence plate
    reader and equilibrate to ambient temperature (20–25 °C) for
    5 min.

  11. Read the fl uorescence using an excitation wavelength of
    355 nm and emission wavelength of 460 nm, using time scales
    and intervals described above.

  12. Plot the FU versus T for each substrate concentration.

  13. Calculate the reaction rate (FU/ T ) for each substrate concen-
    tration, as above.

  14. Plot substrate concentration versus reaction rate. This should
    give a hyperbolic plot, where the y value approaches V max. If
    the plot is not hyperbolic, the substrate range used in the assay
    may need to be altered.

  15. Plot 1/[substrate] versus 1/reaction rate (Lineweaver–Burk
    plot). The slope of the fi tted line is equal to 1/ Km. Alternatively,
    a program such as GraFit or Prism can be used to automati-
    cally calculate Km.

  16. Prepare protein by concentrating or diluting to between 200
    and 400 μg/mL in 1× Assay buffer. This is a 40× working
    solution, giving a fi nal assay concentration of 5–10 μg/mL.

  17. Dilute the inhibitor to 100 μM in ddH 2 O (stock inhibitor)
    and place a 96-well black-bottomed plate on ice.

  18. Dilute a fl uorogenic substrate to 100 μM in ddH 2 O, preparing
    enough for 20 μL per well.


3.5.4 Calculation of Km


3.5.5 Calculation of IC 50 s
for Inhibitors


Karen McLuskey et al.

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