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Measuring a cell’s ability to proliferate is a fundamental method for assessing cell health, determining genotoxicity, and evaluating anti-cancer drugs. The most accurate method is by directly measuring DNA synthesis. Initially, this was performed by incorporation of radioactive nucleosides, i.e., 3H-thymidine. This method was replaced by antibody-based detection of the nucleoside analog bromo-deoxyuridine (BrdU). The Click-iT® EdU Flow Cytometry Assay Kits are novel alternatives to the BrdU assay. EdU (5-ethynyl-2´-deoxyuridine) is a nucleoside analog to thymidine and is incorporated into DNA during active DNA synthesis. Detection is based on a click reaction (1-4), a copper catalyzed covalent reaction between an azide and an alkyne. In this application, the alkyne is found in the ethynyl moiety of EdU, while the azide is coupled to Pacific Blue™ dye, Alexa Fluor® 647 dye, or Alexa Fluor® 488 dye. Standard flow cytometry methods are used for determining the percentage of S-phase cells in the population (Figure 1).
The advantage of Click-iT® EdU labeling is that the small size of the dye azide allows for efficient detection of the incorporated EdU using mild conditions. Standard aldehyde-based fixation and detergent permeabilization are sufficient for the Click-iT® detection reagent to gain access to the DNA. This is in contrast to BrdU assays that require DNA denaturation (using acid, heat, or digestion with DNase) to expose the BrdU so that it may be detected with an anti-BrdU antibody. Sample processing for the BrdU assay can result in signal alteration of the cell cycle distribution as well as the destruction of antigen recognition sites when using the acid denaturation method. In contrast, the EdU cell proliferation kit is compatible with cell cycle dyes (Figure 2). The EdU assay can also be multiplexed with antibodies against surface and intracellular markers. However, some reagents or antibody conjugates may not be compatible with the Click-iT® EdU detection reaction and may need some additional steps to ensure compatibility (see Table1).
Figure 1. Fluorescence signal from Pacific Blue™, Alexa Fluor® 488, and Alexa Fluor® 647 Click-iT® EdU Flow Cytometry Assay Kits. Jurkat (human T-cell leukemia) cells were treated with 10 μM EdU for 2 hours and detected according to the recommended staining protocol. The figures show a clear separation of proliferating cells which have incorporated EdU and nonproliferating cells which have not. Panel A shows data from cells labeled with Pacific Blue™ azide analyzed on an Attune® Acoustic Focusing Cytometer using 405 nm excitation with a 450/40 nm bandpass emission filter; Panel B shows data from cells labeled with Alexa Fluor® 488 azide analyzed on an Attune® Acoustic Focusing Cytometer using 488 nm excitation and a 530/30 nm bandpass emission filter; Panel C shows data from cells labeled with Alexa Fluor® 647 azide analyzed on a flow cytometer using 633 nm excitation and a 660/20 nm bandpass emission filter. |
Figure 2. Dual parameter plot of Click-iT® EdU Alexa Fluor® 488 and FxCycle™ Violet. Jurkat (human T-cell leukemia) cells were treated with 10 μM EdU for 2 hours and detected according to the recommended staining protocol. Data was collected and analyzed using an Attune® Acoustic Cytometer using 488 nm excitation and a 530/30 bandpass for detection of the EdU Alexa Fluor® 488 azide and 405 nm excitation and a 450/40 bandpass for detection of the FxCycle™ Violet fluorescence. This figure combines DNA content with EdU; cells that are positive for both labels are in S-phase of the cell cycle. |
Table 1. Click-iT® EdU detection reagent compatibility
Fluorescent molecule | Compatibility* |
---|---|
Qdot® nanocrystals | Use Qdot® nanocrystals after the Click-iT® detection reaction. |
Fluorescent proteins (GFP) | Use anti-GFP antibodies before the Click-iT® detection reaction or use organic dye-based reagents for protein expression detection. |
Organic dyes such as Alexa Fluor® dyes, fluorescein (FITC) | Compatible |
PerCP, allophycocyanin (APC) and APC-based tandems (i.e., Alexa Fluor® 680-APC) | Compatible |
R-phycoerythrin (R-PE) and R-PE based tandems (i.e., Alexa Fluor® 610-RPE) | Use R-PE and R-PE-based tandems after the Click‑iT® detection reaction. |
TC-FlAsH™/TC-ReAsH™ reagents | Detect the tetracysteine (TC) tag with FlAsH™ or ReAsH™ reagents before the Click-iT® detection reaction. |
*Compatibility indicates whether fluorescent molecule itself or the detection methods involve components that are unstable in the presence of copper catalyst used for the Click-iT® EdU detection reaction. Not all anti- GFP antibodies recognize the same antigen site. Rabbit and chicken anti-GFP antibodies perform well, but the mouse monoclonal antibodies tested do not generate an acceptable amount of fluorescence and are not recommended for this application. |
Material | Amount | Concentration | Storage* | Stability |
---|---|---|---|---|
EdU (Component A) | 10 mg | NA |
2–6°C Desiccate Protect from light Do not freeze |
When stored as directed, this kit is stable for up to 1 year after receipt. |
Alexa Fluor® 488 azide (Cat. no. C10425), Alexa Fluor® 647 azide (Cat. no. C10424), or Pacific Blue™ azide (Cat. no. C10418) (Component B) | 1 vial | NA | ||
Dimethylsulfoxide (DMSO) (Component C) | 4.25 mL | NA | ||
Click-iT® fixative (Component D) | 5 mL | 4% paraformaldehyde in PBS | ||
Click-iT® saponin-based permeabilization and wash reagent (Component E) | 50 mL | 10X solution | ||
CuSO4 (Component F) | 0.5 mL | 100 mM aqueous solution | ||
Click-iT® EdU buffer additive (Component G) | 400 mg | NA | ||
*These storage conditions are appropriate when storing the entire kit upon receipt. For optimal storage conditions for each component, see vial labels. NA = Not applicable. | ||||
Number of assays: Sufficient material is supplied for 50 reactions, based on the protocol below. | ||||
Approximate fluorescence excitation/emission maxima: Pacific Blue™ azide: 410/455 nm; Alexa Fluor® 647 azide: 650/670 nm; Alexa Fluor® 488 azide: 495/519 nm. |
1.1 Allow vials to warm to room temperature before opening.
1.2 To prepare a 10 mM solution of EdU, add 4 mL of DMSO (Component C) or aqueous solution (PBS) to Component A and mix well. After use, store any remaining stock solution at ≤–20°C. When stored as directed, the stock solution is stable for up to 1 year.
1.3 To prepare a working solution of Pacific Blue™ azide (Cat. no. C10418), Alexa Fluor® 647 azide (Cat. no. C10424), or Alexa Fluor® 488 azide (Cat. no. C10425), add 130 μL of DMSO to Component B and mix well. After use, store any remaining working solution at ≤–20°C. When stored as directed, this working solution is stable for up to 1 year.
1.4 To prepare 500 mL of 1X Click-iT® saponin-based permeabilization and wash reagent, add 50 mL of Component E to 450 mL of 1% BSA in PBS. Smaller amounts can be prepared by diluting a volume of Component E 1:10 with 1% BSA in PBS. After use, store any remaining solutions at 2–6˚C. When stored as directed, the 1X solution is stable for 6 months and the 10X solution is stable for 12 months after receipt. Note: Component E contains sodium azide (see Cautions).
1.5 To make a 10X stock solution of the Click-iT® EdU buffer additive (Component G), add 2 mL of deionized water to the vial and mix until the Click-iT® EdU buffer additive is fully dissolved. After use, store any remaining stock solution at ≤–20˚C. When stored as directed, the stock solution is stable for up to 1 year.
The following protocol was developed with Jurkat cells, a human T cell line, and using an EdU concentration of 10 μM, and can be adapted for any cell type. Growth medium, cell density, cell type variations, and other factors may influence labeling. In initial experiments, we recommend testing a range of EdU concentrations to determine the optimal concentration for your cell type and experimental conditions. If currently using a BrdU based assay for cell proliferation, a similar concentration to BrdU is a good starting concentration for EdU. If using whole blood as the sample, we recommend heparin as the anticoagulant for collection.
2.1 Suspend the cells in an appropriate tissue culture medium to obtain optimal conditions for cell growth. Disturbing the cells by temperature changes or washing prior to incubation with EdU slows the growth of the cells during incorporation.
2.2 Add EdU to the culture medium at the desired final concentration and mix well. We recommend a starting concentration of 10 μM for 1–2 hours. For longer incubations, use lower concentrations. For shorter incubations, higher concentrations may be required. For a negative staining control, include cells from the same population that have not been treated with EdU.
2.3 Incubate under conditions optimal for cell type for the desired length of time. Altering the amount of time the cells are exposed to EdU or subjecting the cells to pulse labeling with EdU allows the evaluation of various DNA synthesis and proliferation parameters. Effective time intervals for pulse labeling and the length of each pulse depend on the cell growth rate.
2.4 Harvest cells and proceed immediately to step 3.1 if performing antibody surface labeling; otherwise continue to step 4.1.
3.1 Wash cells once with 3 mL of 1% BSA in PBS, pellet cells by centrifugation, and remove supernatant.
3.2 Dislodge the pellet and resuspend cells at 1 × 107 cells/mL in 1% BSA in PBS.
3.3 Add 100 μL of cell suspension or whole blood sample to flow tubes.
3.4 Add surface antibodies and mix well (Table 2, page 3). Note: Do not use PE, PE-tandem, or Qdot® antibody conjugates before performing the click reaction; wait until step 6.1 for labeling with these fluorophores.
3.5 Incubate for the recommended time and temperature, protected from light. 3.6 Proceed to step 4.1 for cell fixation.
The Click-iT® saponin-based permeabilization and wash reagent can be used with whole blood or cell suspensions containing red blood cells, as well as with cell suspensions containing more than one cell type. This permeabilization and wash reagent maintains the morphological light scatter characteristics of leukocytes while lysing red blood cells.
4.1 Wash the cells once with 3 mL of 1% BSA in PBS, pellet the cells, and remove the supernatant.
4.2 Dislodge the pellet, add 100 μL of Click-iT® fixative (Component D), and mix well.
4.3 Incubate the cells for 15 minutes at room temperature, protected from light.
4.4 Wash the cells with 3 mL of 1% BSA in PBS, pellet the cells, and remove the supernatant. Repeat the wash step if red blood cells or hemoglobin are present in the sample. Remove all residual red blood cell debris and hemoglobin before proceeding.
4.5 Dislodge the cell pellet and resuspend the cells in 100 μL of 1X Click-iT® saponin-based permeabilization and wash reagent (prepared in step 1.4), and mix well. Incubate the cells for 15 minutes or proceed directly to step 5.1 for click labeling.
5.1 Prepare 1X Click-iT® EdU buffer additive by diluting the 10X stock solution (prepared in step 1.5) 1:10 in deionized water.
5.2 Prepare the Click-iT® reaction cocktail according to Table 2.
Note: Use the Click-iT® reaction cocktail within 15 minutes of preparation.
Table 2. Click-iT® EdU Reaction Cocktails
Reaction Components | Number of Reactions | ||||||
---|---|---|---|---|---|---|---|
1 | 2 | 5 | 10 | 15 | 30 | 50 | |
PBS, D-PBS, or TBS | 438 µL | 875 µL | 2.19 mL | 4.38 mL | 6.57 mL | 13.2 mL | 21.9 mL |
CuSO4 (Component F) | 10 µL | 20 µL | 50 µL | 100 µL | 150 µL | 300 µL | 500 µL |
Fluorescent dye azide (prepared in step 1.3) | 2.5 µL | 5 µL | 12.5 µL | 25 µL | 37.5 µL | 75 µL | 125 µL |
Reaction Buffer Additive (prepared in step 5.1) | 50 µL | 100 µL | 250 µL | 500 µL | 750 µL | 1.5 mL | 2.5 mL |
Total reaction volume | 500 µL | 1 mL | 2.5 mL | 5 mL | 7.5 mL | 15 mL | 25 mL |
5.3 Add 0.5 mL of Click-iT® reaction cocktail to each tube and mix well.
5.4 Incubate the reaction mixture for 30 minutes at room temperature, protected from light.
5.5 Wash the cells once with 3 mL of 1X Click-iT® saponin-based permeabilization and wash reagent (prepared in step 1.4), pellet the cells, and remove the supernatant. Dislodge the cell pellet and resuspend the cells in 100 μL of 1X Click-iT® saponin-based permeabilization and wash reagent, if proceeding with intracellular antibody labeling in step 6.1. Otherwise, add 500 μL of 1X Click-iT® saponin-based permeabilization and wash reagent and proceed with step 7.1 for staining the cells for DNA content, or with step 8.1 for analyzing the cells on a flow cytometer.
7.1 If necessary, add Ribonuclease A to each tube and mix (Table 3).
Table 3. Click-iT® EdU compatibility with DNA content stains
DNA Content Stain | Click-iT® EdU Stain Compatibility | RNase required? | ||
---|---|---|---|---|
Pacific Blue™ | Alexa Fluor® 647 | Alexa Fluor® 488 | ||
FxCycle™ Violet | No | Yes | Yes | No |
Propidium iodide (PI) | Yes | Yes | No* | Yes |
SYTOX® AADvanced™ | Yes | Yes | Yes | Yes |
FxCycle™ Far Red | Yes | No | Yes | Yes |
7.2 Add the appropriate DNA stain to each tube, mix well, and incubate as recommended for each DNA stain.
If measuring total DNA content on a traditional flow cytometer using hydrodynamic focusing, use a low flow rate during acquisition. If using the Attune® Acoustic Focusing Cytometer, all collection rates may be used without loss of signal integrity if the event rate is kept below 10,000 events per second. However, for each sample within an experiment, the same collection rate and cell concentration should be used. The fluorescent signal generated by DNA content stains is best detected with linear amplification. The fluorescent signal generated by Click-iT® EdU labeling is best detected with logarithmic amplification.
8.1 Analyze the cells using a flow cytometer.