Cell Cycle Analysis: Assessing CD4 and CD8 T Cell Proliferation After Stimulation Using CFSE Staining and Flow Cytometry

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Cell Cycle Analysis: Assessing CD4 and CD8 T Cell Proliferation After Stimulation Using CFSE Staining and Flow Cytometry

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10:57 min

April 30, 2023

Vue d'ensemble

Source: Perchet Thibaut1,2,3, Meunier Sylvain1,2,3, Sophie Novault4, Rachel Golub1,2,3
1 Unit for Lymphpoiesis, Department of Immunology, Pasteur Institute, Paris, France
2 INSERM U1223, Paris, France
3 Université Paris Diderot, Sorbonne Paris Cité, Cellule Pasteur, Paris, France
4 Flow Cytometry Platfrom, Cytometry and Biomarkers UtechS, Center for Translational Science, Pasteur Institute, Paris, France

The cell cycle is a universal process of life. During the cell cycle, a cell undergoes several modifications to divide into two daughter cells. This mechanism occurs throughout an organism's life in response to its needs. Cell divisions and embryonic development produce a full organism from a single-celled zygote. During adulthood, the cell cycle is central to many critical biological processes, such as tissue repairs.

Mechanisms of cell division are tightly controlled events where the cell undergoes stepwise modifications before final division. Cells that are not yet in the cycle are described as being in the Gap 0 (G0) phase. During this stage the cell is considered quiescent. When the cell starts to cycle, four distinct phases are recognized: Gap 1 (G1), Synthesis (S), Gap 2 (G2) and Mitosis (M). G1 phase is a checkpoint for resources needed by the cell for DNA synthesis. Then, S phase occurs, and DNA replication starts, followed by the G2 interphase, another checkpoint that controls all elements necessary to for the cell to divide. Finally, the cell enters mitosis and divides into two daughter cells.

Cell division is a highly informative parameter in many different biological systems. In the field of immunology, analysis of leukocyte proliferation can indicate the mechanism of the immune response. Other domains of investigation also rely on cell cycle analysis. For instance, analysis of the cell cycle during tumor development has improved our understanding of cancer.

Many fluorescent dyes are now available for tracking cell proliferation. These dyes differ in their chemical and spectral properties. Two different classes of dyes exist: protein dyes permanently combine with protein by forming a covalent bond, and membrane dyes stably intercalate within cell membranes via strong hydrophobic associations. In vitro and in vivo studies of immune cell proliferation by flow cytometry are among the most common applications of both classes of cell tracking dyes (1, 2).

CFSE (Carboxyfluorescein succinimidyl ester) is a fluorescent dye that marks dividing cells. Initially, all the cells receive the same amount of dye; dividing cells evenly split the dye they received between their two daughter cells. Consequently, the cell cycle can be followed by the progressive decrease of dye intensity in the cells. CFSE staining is followed by conventional multi-parametric flow cytometry, a high-throughput, fluorescence-based technology that allows phenotypic and functional characterization of cells based on their degree of CFSE staining (3).

In the following experiment, we assess the proliferation of CD4+ and CD8+ T cells in-vitro, following CD3 stimulation, using CFSE staining and flow cytometry.

Procédure

1. Preparation

  1. Before beginning, put on laboratory gloves and the appropriate protective clothing.
  2. Sterilize all the dissection tools, first with a detergent and then with 70% ethanol and then wipe them dry thoroughly.
  3. Prepare 50 mL of Hank's balanced salt solution (HBSS) containing 2% fetal calf serum (FCS).

2. Dissection

  1. Using a carbon dioxide delivery system, euthanize the mouse by hypoxia. Secure the euthanized mouse on a dissection plate in the supine position and perform a longitudinal laparotomy using scissors and forceps.
  2. Using forceps, move the intestines and stomach on the right side of the abdomen to expose the stomach and spleen. The spleen is attached to the stomach.
  3. Using forceps carefully detach the spleen from the stomach and place it in the Petri dish containing 5 mL of HBSS 2% FCS.

3. Immune Cell Isolation

  1. Place the spleen on a 40 µm cell strainer over the same Petri dish. Crush the spleen with a plunger to dissociate it.
  2. Transfer the dissociated spleen and the fluid into a 15 mL centrifuge tube.
  3. Centrifuge the tube at 370 x g for 7 min at 10°C and discard the supernatant avoiding the pellet.
  4. Resuspend the pellet in 2 mL of potassium acetate to lyse the erythrocytes. Wait for 2 min and then make up the volume up to 15 mL using HBSS 2% FCS.
  5. Centrifuge the tube again at 370 x g for 7 min at 10°C. Discard the supernatant and resuspend the pellet in 5 mL of HBSS 2% FCS.
  6. Count the cells using a trypan blue staining assay and adjust the final cell concentration to 107 cells/mL using an appropriate volume of HBSS 2% FCS.

4. CFSE Staining and T-cell Stimulation

  1. Distribute 107 isolated spleen cells/tube in 4 tubes (15 mL tubes, labeled 1 to 4)
  2. Add 3 mL HBSS 2%FCS to each tube.
  3. Add 1 µL of CSFE in each tube (final concentration- 5 µM).
  4. Incubate the tubes at 37°C in a 5% CO2 incubator for 10 min.
  5. In tubes 3 and 4, add 12 mL of HBSS 2% FCS + anti-CD3 antibody at a final concentration of 2.5 µg/mL. Tubes 3 and 4 are be stimulated using anti-CD3 antibody, to observe the effect on the cell cycle.
  6. In tubes 1 and 2 add 12 mL of HBSS 2% FCS. The cells in tubes 1 and 2 will not be stimulated.
  7. Centrifuge all the tubes at 370 x g for 7 min at 10°C. Discard the supernatants.
  8. Resuspend the pellets in 2 mL of HBSS 2%FCS.
  9. Transfer the resulting solutions into separate wells on a 6-well plate.
  10. Incubate the cells at 37°C, 5% CO2 for 3 days.

5. Cell Staining

  1. On day 3, add 2 mL HBSS 2%FCS in well 1 and 3.
  2. Pipet vigorously and transfer the samples into 5 mL FACS tubes.
  3. Continue incubating the remaining cells from wells 2-4 at 37°C, 5% CO2. They will be analyzed on day 5 to investigate the long-term effects of stimulation on the cell cycle.
  4. Centrifuge the tubes at 370 x g for 7 min at 10°C. Discard the supernatants.
  5. Add 100 µL of antibody mix (see Table 1) to each tube.
Antibody Fluorochrome Dilution
CD3 Pacific Blue 1/100
CD4 BV786 1/1600
CD8 PE 1/400
Thy1.2 BV605 1/400

Table 1: Antibody mix composition. Four antibody cocktail preparations using concentrated antibody-fluorescent conjugates and HBSS.

  1. Incubate the tubes for 20 min on ice in the dark.
  2. Add 1 mL of HBSS 2%FCS and centrifuge the tubes at 370 x g for 7 min at 10°C.
  3. Discard the supernatant and resuspend the pellets in 200 µL of HBSS 2% FCS.
  4. Transfer the resuspended pellets to new, labelled FACS tubes.
  5. Evaluate T-cell proliferation using FACS.
  6. On day 5, repeat the cell staining process with the cells from the remaining two wells of the 6-well plate.

6. Data Analysis

  1. Open the "FlowJo" software and drag the files into the "All sample" window.
  2. Double click on the file for unstimulated cells collected on day 3 to display a dot plot with forward scatter on the Y axis and side scatter on the X axis.
  3. Click on "Polygon" and create a gating strategy to select lymphoid cells, Thy1.2+ CD3+ cells and distinguish CD4+ and CD8+ cells (see Figure 1).

Figure 1
Figure 1: Gating strategy. Cells are first gated based on their morphology (left: FSC-A, SSC-A). T cells are then gated (middle: CD3, Thy1.2) and further divided on CD4+ T cells (orange) and CD8+ T cells (blue) (right: CD4, CD8). Please click here to view a larger version of this figure.

  1. Repeat the steps with other files.
  2. To determine the frequencies of dividing and non-dividing cells, first visualize the cell populations by clicking on "Layout editor."
  3. Drag the CD4 T cells and CD8 T cells from each of the four tubes to the "All sample window"
  4. Graphs representing each population will appear.
  5. Use histogram to visualize the results and select "CFSE" as parameter for comparison of the different tubes and the different populations.
  6. Non-dividing cells maintain higher levels of CFSE, whereas proliferating cells split the content of CFSE to dividing cells
  7. Create a gate on non-dividing cells and apply it in all tubes.
  8. Create a gate on dividing cells and apply it in all tubes.
  9. To examine the frequency of dividing CD3+ cells, click on "Table editor."
  10. Drag the populations of interest – dividing CD8 T-cells and dividing CD4 T-cells – into "Table."
  11. On the "Statistic" menu, select "frequency of T cells," then click on "Create table" to reveal the frequency in a new table.
  12. Click on "Create table." To reveal the frequency values, appear on a new table.

For most immunology studies, measuring proliferation of immune cells is a key step and the CFSE fluorescent dye-based method is commonly used. Proper cell division is important for immune cells since it regulates both levels and specificity of an immune response. For example, T-cells proliferate to identify and kill cancer cells and B-cells undergo cell division to produce specific antibodies. The overall premise of the CSFE assay involves staining the cells with the green fluorescent dye CFSE, which enters live cells and stably binds to the proteins inside, resulting in permanent labeling. As a result, when the dye-containing parent cell divides, each daughter cell gets half the fluorescence from the parent cell.

This process continues in the subsequent divisions with the dye intensity progressively decreasing with each division. At the desired endpoint, the fluorescence intensity of each cell is measured by flow cytometry. This data is then used to quantify the number and pattern of divisions the cells have gone through. As shown here, the cell population with the highest fluorescence are from the parent generation. The second highest belongs to the second generation and so on. The number of peaks determines the number of cell divisions.

In addition, if primary immune cells are used, specific cell populations, like the T-cells for example, can be labeled with a different colored fluorescence dye along with CFSE, and simultaneously identified using multicolor flow cytometry. The new data can be plotted on the same graph, now showing the T-cell sub-population with different CFSE staining intensities, by which the proliferation rate of the T-cells can be specifically analyzed. This video demonstrates the protocol for CFSE staining of mouse splenocytes, which are stimulated with an anti-CD3 antibody. This is followed by staining to label T-cells and flow cytometry to track their cell proliferation.

To begin, put on appropriate protective clothing and laboratory gloves. Next, wash a pair of forceps and dissecting scissors first with a detergent and then with 70% ethanol and then wipe them dry with a clean paper towel. Prepare 50 milliliters of Hank's Balanced Salt Solution, or HBSS, with a 2% concentration of fetal calf serum, or FCS, by combining one milliliter of FCS with 49 milliliters of HBSS in a 50 milliliter tube. Mix by gently pipetting the solution up and down approximately 10 times. Then, isolate mouse spleen cells as demonstrated in the video protocol for FACS isolation of splenic B-lymphocytes.

Label four 15-milliliter tubes one through four and add one times 10 to the seventh isolated spleen cells. Next, add three milliliters of HBSS 2% FCS to each tube. Then, pipette one microliter of five micromolar carboxyfluorescein succinimidyl ester, or CFSE, into each tube. Incubate the tubes at 37 degrees Celsius in a 5% carbon dioxide incubator for 10 minutes. The cells in tubes one and two will not be stimulated. They will be used to reveal the basal level of proliferation of splenic CD4 and CD8 T-cells.

Pipette 10 milliliters of HBSS 2% FCS into these tubes. Tubes three and four will be stimulated by anti-CD3 antibody in order to observe the effects on the cell cycle. Add 10 milliliters of HBSS 2% FCS and anti-CD3 antibody at a final concentration of 2.5 micrograms per milliliter to tubes three and four. Next, centrifuge all of the tubes at 370 x g for seven minutes at 10 degrees Celsius. Discard the supernatants. Resuspend the pellets in two milliliters of HBSS 2% FCS and pipette the resulting solutions into separate wells on a six-well plate. Carefully label the plate from one to four to keep track of sample identities. Incubate the cells at 37 degrees Celsius and 5% CO2 for three days.

On day three, add two milliliters of HBSS 2% FCS to wells one and three, which should contain the cells from tubes one and three. Pipette up and down vigorously and then transfer the samples into labeled five-milliliter FACS tubes. Place the six-well plate back into the incubator. These remaining cells from wells two and four will be analyzed on day five to investigate long-term effects of stimulation on the cell cycle. Centrifuge the tubes at 370 x g for seven minutes at 10 degrees Celsius and then discard the supernatants. Now, add 100 microliters of antibody mix to each tube. Incubate the tubes for 20 minutes on ice in the dark. Next, add one milliliter of HBSS 2% FCS to each tube and centrifuge the tubes at 370 x g for seven minutes at 10 degrees Celsius. Discard the supernatants. Re-suspend the pellets in 200 milliliters of HBSS 2% FCS and mix well. Transfer the resuspended pellets to new labeled FACS tubes.

Then, evaluate T-cell proliferation using flow cytometry as shown in the FACS protocol. Gate the cells to select lymphoid CD3-positive cells and to distinguish CD4-positive and CD8-positive cells, and record the data for tubes one and three. On day five, repeat the cell-staining process with the cells from the remaining two wells of the six-well plate.

We will analyze the effects of CD3 stimulation on the cell cycle of CD4 and CD8-positive cells at three days and five days post-stimulation. To begin, click on the FlowJo icon and drag your files into the All Sample window. Double-click on the file for the unstimulated cells collected on day three to display a dot plot with forward scatter on the y-axis and side scatter on the x-axis. Click on polygon to circle the lymphocyte populations based on their morphology. In the sub-population identification window, name the population lymphocytes and click OK. Next, double-click on the circled population and in the new window, select Thy1.2 on the y-axis and CD3 on the x-axis. Then, click on polygon to circle the CD3 and Thy1.2 double positive cells. In the new sub-population identification window, name the population T-Cells and click OK. Next, double-click on the circled population. In the new window, select CD4 on the y-axis and CD8 on the x-axis. Then, click on polygon to circle the CD4-positive population. In the new sub-population identification window, name the population CD4 T-Cells and click OK. Now, click on polygon to circle the CD8-positive population. In the new sub-population identification window, name the population CD8 T-Cells and click OK. Repeat these steps with the other files.

To determine the frequencies of dividing and non-dividing cells, first, visualize the cell populations by clicking on Layout Editor. Then, drag the CD4 T-cells and CD8 T-cells from each of the four tubes to the All Sample window. Graphs representing your populations will appear. For each tube, double-click on the dot plot for CD8 T-cells and select Histogram under Graph Definition to visualize the results. Select CFSE as the parameter to compare the stimulated versus unstimulated cell populations at each time point. Non-dividing cells maintain higher levels of CFSE whereas proliferating cells split the content of CFSE to dividing cells.

Now, while pressing the Shift key, double-click on the histogram. In the new window, click range and select the range of CFSE corresponding to the highest peak. In the sub-population identification window, name the population Non-Dividing CD8 T-Cells and label the population Dividing CD8 Cells. Now, repeat to select the dividing and non-dividing CD4 T-cells in each tube. To examine the frequency of dividing CD3-positive cells, click on Table Editor. Then, drag the populations of interest, Dividing CD8 T-Cells and Dividing CD4 T-Cells, into table. On the Statistic menu, select Frequency of T-cells. Then, click on Create Table to reveal the frequency in a new table.

Résultats

In this experiment, we followed proliferation of splenic CD4+ and CD8+ T cells in in vitro culture. After 3 days, we did not see strong proliferation in both CD4+ and CD8+ T cells with or without stimulation. This is can be seen on the top panel of Figure 2 where the peaks of CSFE are not decreasing. However, after 5 days, we started to see proliferation in both populations, which is evident from decrease in the CSFE peaks (bottom panels, Figure 2). CFSE staining, clearly demonstrates that both CD4+ and CD8+ T cells were dividing more after stimulation. In addition, CD8+ T cells seemed to be slightly more proliferative than CD4+ T cells after 5 days of stimulation.

Figure 2
Figure 2: CD4 versus CD8 T cells proliferation. Proliferation of T cells at day 3 (top panel) and day 5 (bottom panel). Cell cycle is compared between CD4 and CD8 T cells with or without stimulation at two different days. CD4 and CD8 T cells proliferate more when stimulated. CD8 stimulated T cells proliferate more than CD4 stimulated T cells at day 5. Please click here to view a larger version of this figure.

Applications and Summary

Proliferation assays are often used in different fields such as immunology to determine the degree of activation of cells. It is also performed in oncology diagnostic to determine tumor aggressiveness in patients. CFSE staining is a useful technique to follow immune cell populations' proliferation over time. Other methods allow characterization of cell cycle. BrdU, an equivalent of CFSE is incorporated only in dividing cells. Recent Fucci mouse model even allows detection of cell cycle phases, without additional staining.

References

  1. Lyons, A. B. and Parish, C. R. Determination of lymphocyte division by flow cytometry. Journal of Immunological Methods. 171 (1): 131-37, (1994).
  2. Lyons, A. B. Analyzing cell division in vivo and in vitro using flow cytometric measurement of CFSE dye dilution. Journal of Immunological Methods. 243 (1-2), 147-154, (2000).
  3. Quah, B. J., Warren H. S., and Parish, C. R. Monitoring lymphocyte proliferation in vitro and in vivo with the intracellular fluorescent dye carboxyfluorescein diacetate succinimidyl ester. Nature Protocols. 2 (9): 2049-56, (2007).

Transcription

For most immunology studies, measuring proliferation of immune cells is a key step and the CFSE fluorescent dye-based method is commonly used. Proper cell division is important for immune cells since it regulates both levels and specificity of an immune response. For example, T-cells proliferate to identify and kill cancer cells and B-cells undergo cell division to produce specific antibodies. The overall premise of the CSFE assay involves staining the cells with the green fluorescent dye CFSE, which enters live cells and stably binds to the proteins inside, resulting in permanent labeling. As a result, when the dye-containing parent cell divides, each daughter cell gets half the fluorescence from the parent cell.

This process continues in the subsequent divisions with the dye intensity progressively decreasing with each division. At the desired endpoint, the fluorescence intensity of each cell is measured by flow cytometry. This data is then used to quantify the number and pattern of divisions the cells have gone through. As shown here, the cell population with the highest fluorescence are from the parent generation. The second highest belongs to the second generation and so on. The number of peaks determines the number of cell divisions.

In addition, if primary immune cells are used, specific cell populations, like the T-cells for example, can be labeled with a different colored fluorescence dye along with CFSE, and simultaneously identified using multicolor flow cytometry. The new data can be plotted on the same graph, now showing the T-cell sub-population with different CFSE staining intensities, by which the proliferation rate of the T-cells can be specifically analyzed. This video demonstrates the protocol for CFSE staining of mouse splenocytes, which are stimulated with an anti-CD3 antibody. This is followed by staining to label T-cells and flow cytometry to track their cell proliferation.

To begin, put on appropriate protective clothing and laboratory gloves. Next, wash a pair of forceps and dissecting scissors first with a detergent and then with 70% ethanol and then wipe them dry with a clean paper towel. Prepare 50 milliliters of Hank’s Balanced Salt Solution, or HBSS, with a 2% concentration of fetal calf serum, or FCS, by combining one milliliter of FCS with 49 milliliters of HBSS in a 50 milliliter tube. Mix by gently pipetting the solution up and down approximately 10 times. Then, isolate mouse spleen cells as demonstrated in the video protocol for FACS isolation of splenic B-lymphocytes.

Label four 15-milliliter tubes one through four and add one times 10 to the seventh isolated spleen cells. Next, add three milliliters of HBSS 2% FCS to each tube. Then, pipette one microliter of five micromolar carboxyfluorescein succinimidyl ester, or CFSE, into each tube. Incubate the tubes at 37 degrees Celsius in a 5% carbon dioxide incubator for 10 minutes. The cells in tubes one and two will not be stimulated. They will be used to reveal the basal level of proliferation of splenic CD4 and CD8 T-cells.

Pipette 10 milliliters of HBSS 2% FCS into these tubes. Tubes three and four will be stimulated by anti-CD3 antibody in order to observe the effects on the cell cycle. Add 10 milliliters of HBSS 2% FCS and anti-CD3 antibody at a final concentration of 2.5 micrograms per milliliter to tubes three and four. Next, centrifuge all of the tubes at 370 x g for seven minutes at 10 degrees Celsius. Discard the supernatants. Resuspend the pellets in two milliliters of HBSS 2% FCS and pipette the resulting solutions into separate wells on a six-well plate. Carefully label the plate from one to four to keep track of sample identities. Incubate the cells at 37 degrees Celsius and 5% CO2 for three days.

On day three, add two milliliters of HBSS 2% FCS to wells one and three, which should contain the cells from tubes one and three. Pipette up and down vigorously and then transfer the samples into labeled five-milliliter FACS tubes. Place the six-well plate back into the incubator. These remaining cells from wells two and four will be analyzed on day five to investigate long-term effects of stimulation on the cell cycle. Centrifuge the tubes at 370 x g for seven minutes at 10 degrees Celsius and then discard the supernatants. Now, add 100 microliters of antibody mix to each tube. Incubate the tubes for 20 minutes on ice in the dark. Next, add one milliliter of HBSS 2% FCS to each tube and centrifuge the tubes at 370 x g for seven minutes at 10 degrees Celsius. Discard the supernatants. Re-suspend the pellets in 200 milliliters of HBSS 2% FCS and mix well. Transfer the resuspended pellets to new labeled FACS tubes.

Then, evaluate T-cell proliferation using flow cytometry as shown in the FACS protocol. Gate the cells to select lymphoid CD3-positive cells and to distinguish CD4-positive and CD8-positive cells, and record the data for tubes one and three. On day five, repeat the cell-staining process with the cells from the remaining two wells of the six-well plate.

We will analyze the effects of CD3 stimulation on the cell cycle of CD4 and CD8-positive cells at three days and five days post-stimulation. To begin, click on the FlowJo icon and drag your files into the All Sample window. Double-click on the file for the unstimulated cells collected on day three to display a dot plot with forward scatter on the y-axis and side scatter on the x-axis. Click on polygon to circle the lymphocyte populations based on their morphology. In the sub-population identification window, name the population lymphocytes and click OK. Next, double-click on the circled population and in the new window, select Thy1.2 on the y-axis and CD3 on the x-axis. Then, click on polygon to circle the CD3 and Thy1.2 double positive cells. In the new sub-population identification window, name the population T-Cells and click OK. Next, double-click on the circled population. In the new window, select CD4 on the y-axis and CD8 on the x-axis. Then, click on polygon to circle the CD4-positive population. In the new sub-population identification window, name the population CD4 T-Cells and click OK. Now, click on polygon to circle the CD8-positive population. In the new sub-population identification window, name the population CD8 T-Cells and click OK. Repeat these steps with the other files.

To determine the frequencies of dividing and non-dividing cells, first, visualize the cell populations by clicking on Layout Editor. Then, drag the CD4 T-cells and CD8 T-cells from each of the four tubes to the All Sample window. Graphs representing your populations will appear. For each tube, double-click on the dot plot for CD8 T-cells and select Histogram under Graph Definition to visualize the results. Select CFSE as the parameter to compare the stimulated versus unstimulated cell populations at each time point. Non-dividing cells maintain higher levels of CFSE whereas proliferating cells split the content of CFSE to dividing cells.

Now, while pressing the Shift key, double-click on the histogram. In the new window, click range and select the range of CFSE corresponding to the highest peak. In the sub-population identification window, name the population Non-Dividing CD8 T-Cells and label the population Dividing CD8 Cells. Now, repeat to select the dividing and non-dividing CD4 T-cells in each tube. To examine the frequency of dividing CD3-positive cells, click on Table Editor. Then, drag the populations of interest, Dividing CD8 T-Cells and Dividing CD4 T-Cells, into table. On the Statistic menu, select Frequency of T-cells. Then, click on Create Table to reveal the frequency in a new table.