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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

This article illustrates a powerful method to quantify mitochondria or lysosomes in living cells. The combination of lysosome- or mitochondria-specific dyes with fluorescently conjugated antibodies against surface markers allows the quantification of these organelles in mixed cell populations, like primary cells harvested from tissue samples, by using multicolor flow cytometry.

Abstract

T cells utilize different metabolic programs to match their functional needs during differentiation and proliferation. Mitochondria are crucial cellular components responsible for supplying cell energy; however, excess mitochondria also produce reactive oxygen species (ROS) that could cause cell death. Therefore, the number of mitochondria must constantly be adjusted to fit the needs of the cells. This dynamic regulation is achieved in part through the function of lysosomes that remove surplus/damaged organelles and macromolecules. Hence, cellular mitochondrial and lysosomal contents are key indicators to evaluate the metabolic adjustment of cells. With the development of probes for organelles, well-characterized lysosome or mitochondria-specific dyes have become available in various formats to label cellular lysosomes and mitochondria. Multicolor flow cytometry is a common tool to profile cell phenotypes, and has the capability to be integrated with other assays. Here, we present a detailed protocol of how to combine organelle-specific dyes with surface markers staining to measure the amount of lysosomes and mitochondria in different T cell populations on a flow cytometer.

Introduction

The activation and proliferation of T cells are critical steps for mounting successful immune responses. Recent advances suggest that the cellular metabolism is tightly associated with both the development and functions of T cells. For example, naive T cells rely largely on oxidative phosphorylation (OXPHOS) to meet the energy demand during the recirculation among secondary lymphoid organs. Upon activation, naive T cells undergo drastic metabolic reprogramming, including the induction of aerobic glycolysis to increase ATP production and to fulfill the tremendous metabolic demands during cell differentiation and proliferation. The cells that fail to follow through the metabolic needs die by apoptosis1,2. During the metabolic reprogramming, mitochondria play important roles since they are the organelles largely responsible for the production of ATP to supply energy for the cell, and the cellular mitochondria content fluctuates during metabolic switches throughout T cell development and activation3. However, the accumulation of superfluous or damaged mitochondria can produce excess ROS that damage lipids, proteins, and DNA, and can eventually lead to cell death4

The excessive or damaged mitochondria resulting from metabolic alterations are removed by a specialized form of autophagy5, known as mitophagy. Mitochondria are wrapped by autophagosomes and then fused with lysosomes for degradation. These close communications between mitochondria and lysosomes have generated great interest6,7. For example, oxidative stress stimulates mitochondria to form mitochondria-derived vesicles (MDVs) that are targeted to lysosomes for degradation in a phosphatase and tensin homolog (PTEN)-induced putative kinase 1 (PINK1) and parkin (an E3 ubiquitin ligase) dependent manner8. It was also found that mitophagy is essential for beige-to-white adipocyte transition9,10. More importantly, lysosomes are not merely a degradation compartment, but also a regulator of cellular signaling. Excessive substrate accumulation due to enzyme deficiencies results in lysosomal dysfunction by disrupting lysosomal membrane permeability and affects Ca2+ homeostasis11. The T cell functional defects in lysosomal acid lipase (LAL)12 or lysosomal metabolite transporter knockout mouse model13 further showed the importance of lysosomes in maintaining T cell homeostasis. Both mitochondria and lysosomes are inseparable parts of cellular metabolic regulation. Therefore, measurement of cellular mitochondrial content has been a crucial indicator to evaluate the T cell metabolic and functional status.

Assays commonly used to quantify cellular mitochondrial or lysosomal contents include immunoblot, electron microscopy, immunofluorescent (IF) staining, and PCR analysis of mitochondrial DNA copy numbers14,15,16. While immunoblot can quantitatively compare protein levels across different samples and electron or IF microscopy can visualize the morphological hallmarks of these organelles17, these assays bear certain technical drawbacks. For example, it is time consuming to acquire sufficient number of cell images with high magnification and resolution or to compare the expression levels of a protein across dozens of samples, making these assays considered to be low throughput methods. Moreover, these assays can only be applied to homogenous cell population, such as cell lines, but not to tissue samples that are composed of mixed populations.

It is also difficult to apply these assays to rare populations, for which the requirement of minimal cell numbers from 106 to 108 is impossible to meet. Finally, cells are usually lysed or fixed during the process, making them incompatible with other methods to extract further information. Compared with the traditional methods, fluorescent-based flow cytometry has a relatively high throughput - the information of all the cells within a sample composed of mixed cell populations can be analyzed and collected simultaneously. In addition, one can detect more than 10 parameters on the same cell and sort the cells based on desired phenotypes for further assays. Reactive fluorescent probes have been used to label lysosomes and mitochondria in live cells and can be detected by flow cytometry18,19. These organelle-specific probes are cell permeable and have physico-chemical characteristics that allow them to be concentrated in specific subcellular locations or organelles. Conveniently, these probes are available in various fluorescent formats, thus enabling their application for multicolor analysis.

This protocol describes in detail how to combine surface marker staining with lysosome- or mitochondria-specific dyes to label lysosomes or mitochondria in live cells. This is especially useful for samples generated from primary tissues and organs, which are often composed of heterogeneous cell populations. Researchers can identify cell populations of interest by their surface marker expression and specifically measure the lysosomal or mitochondrial contents through organelle-specific dyes in these cells. Here, we demonstrate the detailed procedure of flow cytometric analysis that evaluates the lysosomal or mitochondrial mass in the major splenic T cell subpopulations.

Protocol

The mouse tissue harvest procedure described here has been approved by the Institutional Animal Care and Use Committee (IACUC) of National Yang-Ming University.

1. Preparation of Lymphocyte Suspension from Lymphoid Organs

  1. Euthanize the mouse by an approved method such as CO2 inhalation in a transparent acrylic chamber followed by cervical dislocation to ensure death.
    NOTE: Keep the flow rate of CO2 for a 20% displacement per minute of the chamber, and no higher than 5 psi (pound per square inch). It takes 2-3 min for a mouse to lose consciousness. Maintain the CO2 flow at least for 1 min after the animal has stopped breathing (5 - 7 min overall).
  2. Place the mouse on its back on a clean board (e.g. a polystyrene plastic board) and fix the limbs with tape. Rinse with 70% ethanol.
  3. To harvest spleen, cut and open the abdominal cavity with 11-cm dissecting scissors (the spleen is below the stomach and above the left kidney). Remove the spleen with forceps and clean from connective tissues (use scissors if necessary).
  4. To harvest the thymus, cut the diaphragm and the rib cage from both sides with dissecting scissors. Use forceps to lift up the sternum to reveal the entire thoracic cavity. Separate the thymus carefully from surrounding tissues with scissors, and remove any residual connective tissue on a paper towel wetted with PBS.
  5. Mechanically dissociate the tissues with a syringe plunger in a 6-cm dish containing 5 mL ice-cold FACS buffer (PBS supplemented with 2% fetal bovine serum (FBS) and 1 mM EDTA). Transfer the single-cell suspension to a 15-mL centrifuge tube; wash the 6-cm dish with additional 2 mL FACS buffer and combine the wash with cell suspension as well.
  6. Centrifuge the cell suspension (300 x g, for 5 min at 4 °C) and discard the supernatant. Re-suspend the pellet with 2 mL of Ammonium-Chloride-Potassium (ACK) lysing buffer (155 mM NH4Cl, 10 mM KHCO3 and 0.1 mM Na2EDTA) for 1 min at room temperature (RT) to lyse the red blood cells. Neutralize the ACK buffer by adding 10 mL FACS buffer to the cell suspension.
  7. Centrifuge the cell suspension (300 x g, for 5 min at 4 °C) and discard the supernatant. Re-suspend cells in 5 mL of complete RPMI medium (RPMI 1640 medium, supplemented with 44 mM NaHCO3, 10 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES), 100 U/mL penicillin, 100 mg/mL streptomycin, 2 mM L-glutamine, 1 mM sodium pyruvate, 1% MEM non-essential amino acids and 10% FBS).
  8. Filter cell suspension through a cell strainer (pore size 70 µm) to remove cell clumps. Count cells with a hemocytometer or automated cell counter.

2. Quantification of Mitochondria and Lysosomes

NOTE: Perform the organelle-specific dye staining first because the optimal staining condition for these dyes is incubation at 37 °C. The surface marker staining can be significantly reduced because of antibody capping and internalization at that temperature.

  1. Add 1 x 106 cells to round-bottom FACS tubes, centrifuge cells (300 x g, for 5 min at 4 °C) and discard supernatant.
  2. Dilute the probe stock solutions to final working concentration (100 nM MitoTracker Green or LysoTracker Green; henceforth mitochondria- or lysosome-specific dye, respectively) in pre-warmed 37 °C serum-free culture medium. This is the working solution for lysosome- or mitochondria-specific dye.
    NOTE: Test multiple concentrations including the range of working concentrations suggested by manufacturer (20 - 200 nM for the mitochondria-specific dye and 50 - 75 nM for the lysosome-specific dye used here) in order to obtain the best staining efficiency. Choose a cell population that is known to have good expression of staining target (e.g. lysosomes) as positive control (e.g. human CD14+ monocytes). Choose the working concentration based on good separation between negative and positive staining, as well as good cell viability.
  3. Resuspend the cells in 100 µL of lysosome- or mitochondria-specific dye working solution and incubate in 5% CO2 incubator at 37 °C for 15 min or 30 min, respectively.
  4. Add 1 mL of ice-cold FACS buffer to stop the reaction. Pellet cells by centrifugation (300 x g, for 5 min at 4 °C) and discard supernatant. Cells are now ready for surface marker staining.

3. Surface Marker Staining

  1. Block Fc receptors with 100 µL of pre-titrated 2.4G2 hybridoma supernatant on ice for 10 min. Wash cells with 1 mL of FACS buffer and centrifuge (300 x g, for 5 min at 4 °C). Discard supernatant.
  2. Incubate the cells with 50 µL pre-titrated fluorescence-conjugated antibody combination in FACS buffer on ice for 20 min. Avoid light.
    NOTE: Prepare single color-stained cells that include all the fluorescent antibodies present in the antibody combination and cells treated only with organelle-specific dye for setting voltages of each fluorescence detector and compensation adjustment on flow cytometer. Likewise, prepare the Fluorescence Minus One (FMO) as background controls by using cells stained with all the antibodies, but without staining with organelle-specific dyes.
  3. Wash the cells by adding 1 mL of FACS buffer and pellet by centrifugation (300 x g, for 5 min at 4 °C). Discard supernatant.
  4. Resuspend the cells in 300 µL of FACS buffer containing 1 µg/mL propidium iodide (PI) and immediately analyze the samples on flow cytometer.

4. Sample Collection on Flow Cytometer

  1. Turn on the computer, flow cytometer, FACS acquisition software and any other accessory devices depending on the machine platform. Run PBS for around 1 min to ensure the flow line is filled with PBS and sheath buffer. Make sure the flow stream runs smoothly.
  2. Open new experiment and select cytometer parameters (fluorescent detectors) according to manufacturer's instruction. Filter cells through 70-µm cell strainer and vortex prior to the acquisition of each sample to avoid clumps and doublet formation.
  3. Make dot plots of forward scatter (FSC) and side scatter (SSC), which represent cell size and granularity, respectively. Optimize the voltages of FSC and SSC to make sure the cells of interest appear in the plots. Make dot plots of FSC-A vs. FSC-W (or FSC-H) and draw a gate for the single cells.
  4. Make dot plots of each fluorescent parameter. Use unstained cells to determine background signal and use single color-stained controls to adjust voltages of each fluorescent parameter, so that positive and negative cell populations are clearly distinguishable and within the dynamic range of acquisition.
  5. After all the voltages are set, use auto-compensation if available, or manually adjust the compensation with unstained and single color-stained controls to correct the spectral spillover. Apply the compensation to samples.
  6. Make a dot plot of each parameter and draw gates according to your experimental set up. For example, FSC-A vs. FSC-H (or FSC-W) to exclude doublets, followed by FSC-A vs. SSC-A for lymphocyte gating; SSC-A vs. PI (live cells) and CD4 vs. CD8 (Figure 1).
  7. Collect enough events (total cell number) for meaningful comparison between populations. Typically, at least 1,000 events in the population of interest need to be obtained20.
  8. After all the samples are acquired, export flow data to be analyzed by flow cytometry analysis software. Save the experiment as template to preserve the cytometer setting and parameters for applying to similar experiments in the future.

5. Data Analysis

NOTE: There are many tools to analyze flow cytometric data, both commercial and free software. The acquisition software of the flow cytometers can also work for data analysis. Here we used FlowJo as an example.

  1. Start the software and drag the FCS files into the workspace. Click on a sample to open a graphic window. Select parameters to be presented on X and Y axis by clicking on the X and Y axes. Use the toolbar to draw gates according to differentially expressed markers or defined phenotypes of cell populations.
  2. Add gates of each parameter as shown in Figure 1. Drag gates to all samples in the workspace, so that they get identical gating.
  3. Drag the plots to layout editor to create graphical reports.
  4. Display the mean fluorescence intensity (MFI) for each population of interest by clicking the statistics button (Σ) in a graphic window and choosing "Mean" and the appropriate parameter, for example, the channel used to detect organelle-specific dye. Then click "Add".
  5. Click the table editor icon and drag MFI to table editor to create statistical reports. Save as Excel, Text or CSV file to calculate delta MFI (ΔMFI) as MFI (organelle-specific dyes) - MFI (FMO).
    NOTE: Do not calculate MFI between samples acquired with different cytometer settings (voltages, fluorescent channels or compensation). Comparisons of values derived from experiments with different settings are meaningless and biased.
  6. Export all the values from the workspace and plots from layout editor for making tables and figures.

Results

Identification of major T cell subsets in spleen and thymus

In brief, single cell suspensions from spleen and thymus were lysed of red blood cells, incubated with 2.4G2 supernatant, followed by organelle-specific dye and surface marker staining with fluorescence-conjugated antibodies (Table 1). The developmental progression of thymocytes can be described by using antibodies to the co-receptors C...

Discussion

This protocol combines organelle-specific dyes and surface marker staining to quantify the amount of mitochondria or lysosomes in different T cell populations. This method was developed to overcome the limitation of cell number and homogeneity requirements for traditional methods, such as electron microscopy and immunoblot analysis. It is especially useful in analyzing rare cell populations and simultaneously examining multiple cell types at the same time.

The duration of the procedure and the...

Disclosures

The authors declare no conflicts of interests.

Acknowledgements

The development of this protocol was supported by grants from the Taiwan Ministry of Science and Technology (MOST) NSC103-2320-B-010-002-MY2 and MOST104-2628-B-010-002-MY4 to C.L. Hsu. C.W. Wei is a recipient of Excellent Thesis Award of Institute of Microbiology and Immunology, National Yang-Ming University.

Materials

NameCompanyCatalog NumberComments
10 cm Graefe forceps (straight and serrated)Dimeda
11 cm Iris scissors (straight with sharp/sharp heads)Dimeda
15 mL centrifuge tubeThermo Fisher Scientific339650
5 mL syringeTERUMO 
6 cm Petri dishα-plus
70 µm nylon cell strainerSPL Lifesciences93070
Ammonium chloride (NH4Cl)   SigmaA9434
Anti-mouse CD25Biolegend102007Clone:PC61
Anti-mouse CD4Biolegend100453Clone:GK1.5
Anti-mouse CD44Biolegend103029Clone:IM7
Anti-mouse CD62LBiolegend104407Clone:MEL-14
Anti-mouse CD8Biolegend100713Clone:53-6.7
Anti-mouse TCRβBiolegend109233Clone:H57-579
BD LSRFortessaBD Biosciences
Ethylenediaminetetraacetic acid (EDTA)Bio basic6381-92-6
FALCON 5ml Polystyrene Round-Bottom Tube (FACS tube)BD Biosciences352052
FcRgamma II (CD32) Hybridoma (2.4G2)ATCCHB-197 
Fetal Bovine Serum (FBS)HycloneATD161145
Flowjo, LLCBD Biosciences
Hydroxyethyl piperazineethanesulfonic acid (HEPES)SigmaH4034
L-glutamine (200 mM)GibcoA2916801
LysoTracker Green DND26Thermo Fisher ScientificL7526
MEM Non-essential amino acids (100X)Gibco11140050
MitoTracker Green FMThermo Fisher ScientificM7514
Penicillin-Streptomycin (10,000 U/mL)Gibco15140122
Potassium bicarbonate (KHCO3)J.T.baker298-14-6
Propidium iodide solutionSigma25535-16-4
RPMI 1640 medium (powder)Gibco31800089
Sodium bicarbonate (NaHCO3)SigmaS5761
Sodium pyruvate (100 mM)Gibco11360070

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