Assaying Protein Kinase Activity with Radiolabeled ATP

Podsumowanie

Protein kinases are highly evolved signaling enzymes and scaffolds that are critical for inter- and intracellular signal transduction. We present a protocol for measuring kinase activity through the use of radiolabeled adenosine triphosphate ([γ-³²P] ATP), a reliable method to aid in elucidation of cellular signaling regulation.

Streszczenie

Protein kinases are able to govern large-scale cellular changes in response to complex arrays of stimuli, and much effort has been directed at uncovering allosteric details of their regulation. Kinases comprise signaling networks whose defects are often hallmarks of multiple forms of cancer and related diseases, making an assay platform amenable to manipulation of upstream regulatory factors and validation of reaction requirements critical in the search for improved therapeutics. Here, we describe a basic kinase assay that can be easily adapted to suit specific experimental questions including but not limited to testing the effects of biochemical and pharmacological agents, genetic manipulations such as mutation and deletion, as well as cell culture conditions and treatments to probe cell signaling mechanisms. This assay utilizes radiolabeled [γ-³²P] ATP, which allows for quantitative comparisons and clear visualization of results, and can be modified for use with immunoprecipitated or recombinant kinase, specific or typified substrates, all over a wide range of reaction conditions.

Wprowadzenie

Protein kinases are sophisticated enzymes critical for the transmission of cellular signals into appropriate responses¹. Given their roles in maintaining homeostasis and the prevention or promotion of disease states², biochemical methods for assessing kinase activity continue to be powerful tools for delineating the particulars of eukaryotic signaling³. Although strategies utilizing phospho-specific antibodies have been highly informative in terms of measuring the effects of different treatment conditions on cell signaling status⁴, a kinase assay allows for measuring the effects of different treatment conditions directly in terms of the enzymatic activity of a kinase of interest. While there are several options for similar assays that do not use radioactive materials⁵, we continue to rely on this method for robust quantitation of results. There are two typical applications of this assay, both valuable for different reasons: the immunoprecipitated (IP) kinase assay (Figure 1) and the recombinant protein kinase assay (Figure 2).

The IP kinase assay is tremendously useful for identifying factors capable of activating specific protein kinases as well as gauging inhibitory treatment conditions. Briefly, an epitope-tagged kinase of interest is transfected into cultured eukaryotic cells, subjected to a variety of treatments, immunoprecipitated, and assayed for the ability to incorporate radiolabeled phosphate into a model substrate (e.g. myelin basic protein (MBP)). IP kinase assay can also be performed without resorting to overexpression, either by immunoprecipitation of endogenous protein or any number of genome-editing techniques. Because treatments are administered in culture, this method can detect stimulations transmitted through multiple upstream factors or parallel pathways by in vitro readout. One major advantage of this method is that it does not require prior knowledge of direct upstream or downstream factors or phosphorylation sites therein. Moreover, once specific substrates for a kinase of interest have been identified, the same kinase assay protocol can be used with recombinant components to measure specific activity towards natural substrates and identify specific phosphorylation sites when combined with mass spectrometry analysis. Sites identified in this manner can be further validated with kinase assays utilizing substrate mutants. Lastly, this method can also be used to detect and measure autophosphorylation.

The protocol provided here assumes either an optimized protein purification scheme or transfection method for expressing an affinity-tagged kinase of interest in cultured cells. For more detailed expositions of transfection, lysis, immunoprecipitation, and protein purification protocols, we suggest referring to Cold Spring Harbor Protocols⁶. For more information regarding assay development and modification, please refer to Protein Phosphorylation: Selected Methods in Enzymology⁷.

Protokół

1. Kinase Purification Resources and General Immunoprecipitation Pipeline

NOTE: Kinases for use with this assay may be sourced from immunoprecipitates of cultured cells or by recombinant means such as affinity-tagged purification⁶. Below is a general protocol for flag-tagged immunoprecipitation that may have to be modified depending on the kinase of interest. Everything should be kept on ice when possible.

1. Add 2 µL of 1 mg/mL antibody to 200 µL of cell lysates (usually ~1 mg/mL total protein concentration) and incubate at 4 °C for 1 h while rocking.
2. Wash protein A sepharose beads 2-3 times with lysis buffer (see below) by briefly spinning at 4 °C for 30 s to 1 min at 5,000 x g ("touch spin"), removing supernatant with a pipette, and resuspending beads in buffer.
   1. Prepare lysis buffer: 50 mM HEPES pH 7.7, 150 mM NaCl, 1.5 mM MgCl₂, 1 mM EGTA, 10% glycerol, 0.2 mM sodium orthovanadate, 100 mM sodium fluoride, 50 mM β-glycerophosphate, 0.1% Triton X 100 or 0.1% NP-40.
3. Add 30 µL of 50% slurry of protein A sepharose beads in lysis buffer to lysates; incubate at 4 °C for 1 h while rocking.
4. Touch spin at 4 °C to pellet the beads and remove the supernatant.
5. Wash 3 times with 1 mL of bead wash buffer (1 M NaCl, 20 mM Tris pH 7.4).
6. Wash once with 1x kinase reaction buffer (10 mM HEPES pH 8.0, 10 mM MgCl₂). Remove as much buffer as possible without removing beads.

2. Initializing Kinase Reactions

NOTE: For IP kinase assays, ~15 µL of unsuspended beads is a typical starting sample. For recombinant protein kinase assays, typical starting amounts range from 0.1-1.0 µg in 1-10 for 25-50 µL final reaction volumes. Adjust the volumes of recombinant protein samples to be equal with the buffer they are stored in prior to initializing the assay. When using high amounts of kinase, include a carrier protein such as BSA to aid in maintaining protein stability for the duration of the assay.

1. Prepare the 5x kinase reaction buffer given below:
   50 mM HEPES pH 8.0
   50 mM MgCl₂
   50 mM Benzamidine (protease inhibitor)
   50 mM DTT (reduction agent)
   250 µM ATP (unlabeled, or "cold")
2. Keep kinase samples on ice in 1.5 mL tubes. Prepare the following reaction mixture in separate, chilled 1.5 mL tubes:
   21 µL H₂O
   6 µL 5x kinase reaction buffer
   1 µL radiolabeled ("hot") ATP
   2 µL substrate (~5 mg/mL)
   NOTE: For recombinant kinase assays, volume may be adjusted to accommodate purified protein. Calculate such that final reaction volume is 30 µL. Use this recipe to prepare a master mix. Upon receipt of labeled ATP, dilute stock in H₂O to a specific activity of 0.01 mCi/µL prior to adding to reaction mixture.
3. To initialize the assay, add entire reaction mixture to kinase sample and incubate reaction at 30 °C for 5 min to 1 h depending on activity of kinase being assayed.
   NOTE: When working with a kinase whose activity has not been previously assayed, perform a time course of kinase activity with 5 min intervals between time points.

3. Reaction Termination and SDS-PAGE

1. Stop reaction by putting on ice and adding 7.5 µL 5x Laemmli sample buffer ⁶.
2. Heat at 100 °C for 30 s to 2 min in heat block.
3. Touch spin and load 20 µL per well on 10-15% SDS-PAGE gel. Run gel long enough to separate kinase and substrate (typically 1 h at constant power of 5 W) Make sure to keep gel apparatus shielded to limit exposure to ³²P.
   1. Here, use homemade gel apparatuses, but standard commercially available mini-gels are perfectly suitable. Use the dimensions as follows:
      Gels: 8 cm width, 5.5 cm length (resolving), 1.5 mm thickness.
      Combs: 15 wells, 1.5 mm thickness, 2.9 mm width, 16 mm depth

4. Gel Staining and Drying

Caution: For all steps be sure to reduce personal exposure to ³²P by using radioactive shielding and wearing personal protective equipment. For more information on specific steps some helpful references are included.

1. Remove the gel from glass/alumina plates and place in 50 mL Coomassie stain (10% glacial acetic acid, 50% methanol, 0.25% R-250 dye) for 1 h on an orbital shaker set to 50 rpm. For this step use a container that is slightly larger than the gel itself.⁸
2. Move the gel from stain to fixing solution (10% glacial acetic acid, 20% methanol) in order to de-stain. Rock the gel in 600-700 mL of fixing solution overnight on orbital shaker at 50 rpm. Place pieces of foam or knotted laboratory wipes in the container with the gel to absorb the Coomassie dye ^8,9.
3. Remove gel from fixing solution and soak in 200 mL methanol for 1-2 min with gentle agitation until gel turns milky white. This will help prevent cracking during the drying step.
4. Wet a 14 cm x 14 cm piece of qualitative filter paper with methanol and place onto slab gel vacuum dryer. Lay the gel down onto the filter paper front side facing up.
5. Cover the gel with plastic wrap carefully to avoid wrinkles and air bubbles. Run the dryer for 1.5 h at 80 °C. After the vacuum has been attained open the lid and roll out any air bubbles if needed with a soft rubber brayer.

5. Autoradiogram and Scintillation Counts

1. Remove dried gel and attach an autorad marker, phosphorescent ruler or dots to the filter paper on the side of the gel. If using dots make sure they are in an asymmetric pattern. This will align the gel with the film after exposure and development.
2. Use a Geiger counter to check the intensity of the signal. For weaker signals exposure at -70 °C to -80 °C with an intensifying screen will increase the film band density.
3. In a dark room put dried gel in a film cassette with film and an intensifying screen in the following order from top to bottom: gel, film, intensifying screen.
4. Attach the intensifying screen to the lid of the cassette and tape the gel in place to make this step easier. The intensifying screen emits light when irradiated by the beta particles from the ³²P. These light emissions penetrate the film more efficiently than the beta particles.
   1. Make sure the wavelength emitted from the intensifying screen corresponds to a wavelength the film is most sensitive to.
   2. Use a Geiger counter to determine how long to leave exposure for: if cpm count is ~100 or below, try overnight at -70 °C. If count is ~10,000, start with a 1 h exposure and optimize from there.
5. At the conclusion of the exposure remove the film and develop in a medical/X-ray film processor. If the exposure was performed at -70 to -80 °C, either allow the cassette to warm to room temperature to minimize condensation on the film or remove the film immediately before condensation forms¹⁰.
6. Lay the film over the dried gel/filter paper and align the image of the marker/dots with the markers/dots on the dried gel. Mark on the film the bands corresponding to the protein standards. Label the protein standards and which lanes the reactions are for future reference.
7. Excise the bands from the gel that correspond to bands of interest on the film and place them in 7 mL scintillation vials. Add 4 mL of scintillation fluid and count with liquid scintillation counter. Confirm the counter is set to monitor the correct energy spectrum window for ³²P.
   NOTE: Be sure to also excise the band corresponding to substrate from the no-kinase control lane. This will be used to calculate background radiation that will be subtracted from all sample scintillation counts.

6. Analysis of Results

NOTE: The autoradiogram provides a qualitative visualization of results. For accurate quantitation, ³²P incorporation can be measured with a scintillation counter. Data are usually expressed in terms of relative activity, as shown in Figure 1B. As long as uniform conditions are maintained for all samples, relative measurements of specific activity are sufficient to compare treatments.

1. When calculating absolute specific activity values, perform a rigorous optimization of all reaction conditions, including kinase, substrate, and cold ATP concentrations, in order to ensure a linear range of activity over a time course (e.g. 2 x [kinase] = 2 x specific activity). For kinases with high specific activity, perform assays with increased substrate concentration in case kinase activity is limited by amount of substrate.
2. Calculate the specific activity of kinase of interest in units of nanomoles phosphate transferred per min per mg kinase.
   1. Subtract blanks from the cpm in the counted bands.
   2. Calculate the decay of hot ATP: [(1/2)^(t/t_1/2)] x 0.95 where t is the number of days since the reference date (should be provided by vendor), t_1/2 is the half-life of ³²P, which is 14.3 days, and 0.95 reflects the efficiency of the scintillation counter. Example: if using hot ATP that is 28 days old, the decay value should be 0.245.
   3. Calculate the picomoles (pmol) of total ATP in the assay (usually this is equal to the amount of cold ATP in the reaction): assay volume (µL) x [cold ATP] (µM) = total ATP (pmols). Example: 30 µL x 50 µM = 1500 pmol
   4. Calculate cpm/pmol ATP: [µL of hot ATP x (2.2 x 10⁷) x decay factor]/ pmol of cold ATP.
      NOTE: The value of 2.2 x 10⁷ converts 0.01 mCi/µL of ATP to cpm.
   5. Calculate the amount of kinase in the assay in mg. For both recombinant kinase and immunoprecipitated kinases, standard methods such as BCA assays are suitable to determine starting concentrations. Example: wtERK2 0.0002 µg/µL in a 50 µL kinase reaction is 0.01 µg, or 1 x 10^-5 mg.
   6. Calculate total cpm in assay. Assemble 30 µL reactions and run 20 µL from each reaction on a gel. Multiply the cpm counted (after blank subtraction) by a factor of total assay volume/ volume loaded. Continuing the above example, multiply all counts by 1.5, or 30/20.
   7. Calculate the specific activity of the assayed kinase:
      Total cpm in assay)/(cpm/pmol ATP)/(assay time in minutes)/(amount of kinase in mg)
      NOTE: Dividing the above value by 1,000 yields the specific activity in nanomoles/minute/mg
3. Calculate how many mols of phosphate are incorporated into a substrate (as long as its molecular weight is known). This is used to determine the number of phosphosites on a particular protein once the reaction has gone to completion.
   Total cpm in assay)/(cpm/pmol ATP)]/(amount of substrate in pmols)

Wyniki

WNK1 IP kinase assays

Myc-tagged WNK1 was transfected into HEK293 cells and immunoprecipitated with an anti-Myc antibody¹¹. The immunoprecipitate displayed kinase activity towards the model substrate MBP as well as toward itself (Figure 1A). WNK1 mutants were then tested for kinase activity towards MBP by the same method, this time employing GST-tagged constructs (Figure 1B)...

Dyskusje

Kinases are a diverse family of proteins that have evolved extensive functionality in numerous contexts, and kinase assays have been incredibly useful in studying several signaling proteins and have greatly contributed to our current understanding of cellular communication. Notably, the same basic assay was used in characterizing two disparate kinases despite major differences in structure and activity. WNK1 kinase contains an atypical catalytic pocket where the critical lysine has shifted to a unique position and is kno...

Materiały

Name	Company	Catalog Number	Comments
Protein A Sepharose CL-4B	GE Healthcare Life Sciences	17-0963-03
Radiolabeled [γ-32P] ATP	Perkin Elmer	NEG035C010MC
Laemmli Buffer	Bio-Rad	#1610737
Radioactive shielding	Research Products International	BR-006
R-250 dye (Coomassie)	Thermo Fisher	20278
Whatman Grade 3 qualitative filter paper	Whatman	1003-917
Slab gel vacuum dryer	Bio-Rad	Model 583 Gel Dryer #1651745
Autorad marker	Agilent Technologies	420201
Phosphorescent ruler	Sigma Aldrich	R8133
Phosphorescent dots	Sigma Aldrich	L5149
Geiger counter	Ludlum	Model 3 with 44-9 detector
BioMax Cassette 8x10"	Carestream Health	107 2263
BioMax MS Film 8x10"	Carestream Health	829 4985
BioMax MS Intensifying Screen 8x10"	Carestream Health	851 8706
Medical/X-ray film processor	Konica Minolta	SRX-101A
Scintillation vials	Research Products International	125500
Scintillation fluid	MP Biomedicals	188245305
Beckman LS 6500 Scintillation counter	Beckman	LS 6500