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In This Article

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

Summary

Here we describe a microscope-based technique to visualize and quantify the early cascades of events during phagocytosis of pathogens such as the fungi Candida albicans and particulates that are larger than 0.5 µm including zymosan and IgG-coated beads.

Abstract

The mammalian body is equipped with various layers of mechanisms that help to defend itself from pathogen invasions. Professional phagocytes of the immune system — such as neutrophils, dendritic cells, and macrophages — retain the innate ability to detect and clear such invading pathogens through phagocytosis1. Phagocytosis involves choreographed events of membrane reorganization and actin remodeling at the cell surface2,3. Phagocytes successfully internalize and eradicate foreign molecules only when all stages of phagocytosis are fulfilled. These steps include recognition and binding of the pathogen by pattern recognition receptors (PRRs) residing at the cell surface, formation of phagocytic cup through actin-enriched membranous protrusions (pseudopods) to surround the particulate, and scission of the phagosome followed by phagolysosome maturation that results in the killing of the pathogen3,4.

Imaging and quantification of various stages of phagocytosis is instrumental for elucidating the molecular mechanisms of this cellular process. The present manuscript reports methods to study the different phases of phagocytosis. We describe a microscope-based approach to visualize and quantify the binding, phagocytic cup formation, and the internalization of particulate by phagocytes. As phagocytosis occurs when innate receptors on phagocytic cells encounter ligands on a target particle bigger than 0.5 µm, the assays we present here comprise the use of pathogenic fungi Candida albicans and other particulates such as zymosan and IgG-coated beads.

Introduction

Despite the continuous exposure to pathogens such as bacteria, viruses and fungi, our body is well equipped with immune mechanism that provide protection against infection. The innate immune system is the first line of defense against invading pathogens and relies mainly on phagocytic cells that recognize and internalize foreign targets.

Phagocytosis is an evolutionarily conserved cellular process that encompasses the engulfment of unwanted particulates greater than 0.5 µm. Phagocytic cells express a wide range of immune receptors (also known as pattern recognition receptors, PRRs) at the cell surface that enable them to recognize pathogen-associated molecular patterns (PAMPs) present on pathogens prior to engulfment3. Pathogen binding is followed by receptor clustering at the cell surface and triggers the formation of a phagocytic cup. This results in actin-driven membrane remodeling that protrudes around the target, eventually enveloping it and pinching-off to form a discrete phagosomal vacuole2,5. The phagosome then matures and acidifies by subsequent fusion with late endosomes and lysosomes that forms phagolysosome6.

Although phagocytosis is described as receptor-mediated and actin-driven event, this process also relies on spatial-temporal modification of lipids that compose the plasma membrane, such as phosphoinositides (PIs) and sphingolipids7,8. While actin polymerization is dictated by a local accumulation of phosphoinositol-4,5-biphosphate (PI(4,5)P2) at the base of the phagocytic cup, actin depolymerization depends on the conversion of (PI(4,5)P2 to phosphoinositol-3,4,5-biphosphate (PI(3,4,5)P3)3,9. Both modifications are essential as the former leads to successful extension of pseudopods around the target and the latter enables sinking of particles in the cytosol of the phagocyte10.

Cells that have the ability to phagocytose are either professional phagocytes, like macrophages/monocytes, granulocytes/neutrophils, and dendritic cells (DCs) or nonprofessional phagocytes, such as fibroblast and epithelial cells11. Phagocytosis performed by all phagocytes plays a central role in tissue maintenance and remodeling, while phagocytosis performed by professional phagocytes is responsible for the coordination of the innate and adaptive immune response against pathogens. Professional phagocytes do not only engulf and kill the pathogen, but also present antigens to the lymphoid cells of the adaptive immune system. This contributes to the release of pro-inflammatory cytokines and to the engagement of lymphoid cells, therefore leading to the successful blockade of infection12.

Conventional biochemical techniques have been instrumental in gaining knowledge regarding the molecular mechanism of different cellular processes during phagocytosis, such as post-translational modifications and various high-affinity associations between proteins. However, it is difficult to obtain information regarding the spatial and temporal dynamics of phagocytic events using the conventional biochemical methods. Live cell imaging not only allows us to monitor cellular events in a time sensitive manner but also enables us to gain information at a single cell level. Here we describe a method to investigate the different stages of phagocytosis, as well as to analyze the whole process spatiotemporally using confocal microscopy.

Protocol

1. Preparation of DC2.4 and RAW 264.7 Cell Lines

NOTE: The macrophage-like cell line RAW 264.7 and the dendritic cell line DC2.4 are both murine origin, and the following conditions were used to grow the cells.

  1. Grow RAW 264.7 cells in DMEM (Dulbecco's Minimal Eagle's medium) supplemented with 10% inactivated Fetal Bovine Serum (FBS) at 37 °C in a humidified incubator with 5% CO2.
  2. Grow DC2.4 cells in similar conditions with that of RAW 264.7 cells, except use RPMI (Roswell Park Memorial Institute) medium supplemented with L-Glutamine instead of DMEM.

2. Preparation of Fluorescent Conjugated Particulates: C. albicans, Zymosan, IgG-coated Beads

  1. Growing Candida albicans
    1. Inoculate C. albicans strain SC5314 from a frozen glycerol stock in 25 ml of YPD supplemented with Uri (2% Bacto-peptone, 1% yeast extract, 2% glucose and 80 µg/ml Uridine) overnight at 30 °C.
      NOTE: Avoid growing the Candida culture more than an OD600 of 12.
    2. Take 1 ml of the C. albicans and spin it down at 2,000 x g for 5 min at room temperature.
    3. Aspirate the supernatant and re-suspend the pellet with 1 ml of PBS.
    4. Collect the pellet by centrifugation at 2,000 x g for 5 min at room temperature.
    5. Repeat step 2.1.4.
    6. Calculate the multiplicity of infection (MOI) of C. albicans in relation to the number of phagocytes and proceed with the phagocytosis assay as described in section 3. An OD600 of 1 is equivalent to 2.5 x 107 Candida albicans per 1 ml.
      NOTE: Generation of Candida-BFP is described in reference13.
  2. Preparation of Zymosan and IgG-coated Beads
    NOTE: Zymosan is a β-glucan-containing fungal carbohydrate particulate preparation that derived from Saccharomyces cerevisiae. Zymosan is known to evoke inflammatory signals in macrophages and dendritic cells, and it has been used extensively in phagocytosis studies 13,14,15.
    1. Briefly vortex the tube that contains the particulate, and aliquot an amount sufficient for an experiment into a 1.5 ml tube.
      NOTE: Typically we use 1:10 ratio (for one cell, add 10 zymosan particles or IgG-coated beads).
    2. Add 1 ml of ice cold PBS, and collect the particles by centrifuging for 1 min at 10,000 x g.
    3. Aspirate the supernatant and resuspend the pellet in 1 ml ice-cold PBS.
    4. Repeat steps 2.2.2-2.2.3
      NOTE: Proceed to step 2.2.5 or store the tube at 4 °C until use.
    5. Sonicate the particulates for 10 sec in ultrasonic bath sonicator (120 V, 50-60 kHz) in order to avoid any particle aggregation.

3. Phagocytosis

NOTE: Phagocytosis is a complex process that begins with binding of the particles on the cell surface of the phagocytes through interaction of PRRs with ligands on the surface of the particle. Binding is followed by the assembly of actin and its associated proteins at the site of contact, and the formation of a phagocytic cup. The subsequent actin disassembly occurs at the phagosome and results in the complete engulfment of the particulate. Below we describe the different stages of phagocytosis.

  1. Binding Assay
    NOTE: The purpose of this experiment is to monitor the first step of phagocytosis that involves the interaction between the ligands on the target particles and the receptors on the phagocytes.
    1. Seed about 5 x 104 cells in a chamber slide so that they are 60-70% confluent at the time of the experiment. Alternatively, plate cells on cover slips (in 24- or 12-well format) or glass-bottom 96-well plates. Incubate cells overnight at 37 °C humidified incubator with 5% CO2.
      NOTE: Cells can be counted using hemocytometer or a similar technique.
    2. Place the chamber slide (or plate) at 10 °C for 10 min.
    3. Gently remove the medium from each well using a pipette or aspirator.
      CAUTION: Perform this step carefully as each well of a chambered coverglass system is small; it is easy to perturb cells with the tip of a pipette or a strong airflow of an aspirator.
    4. Mix the fluorescently labeled particulates with a cell culture medium (prepared as described above). Add Candida-BFP (at an MOI of 10), fluorescently conjugated-zymosan or latex beads-rabbit IgG-FITC (10 particles per cell) to the cells. Use a final volume of 200 µl media for one chamber well to ensure all cells are covered.
    5. Spin down the chamber slide at 277 x g for 3 min at 10 °C.
      NOTE: This centrifugation step helps to increase the contact between the particulates and the cells, and it synchronizes the binding process.
    6. Immediately transfer the chamber slide to a 37 °C humidified incubator with 5% CO2 for 5 min.
    7. Remove the chamber slide from the incubator and aspirate the media.
    8. Wash the cells 3x with ice-cold PBS.
      NOTE: Check the presence of unbound particles with a light microscope and wash more times with PBS if necessary. It is essential to remove unbound particles from the well to minimize background noise during the analysis.
    9. Fix cells by adding 500 µl 4% paraformaldehyde (PFA) diluted in PBS by incubating for 30 min at room temperature.
      CAUTION: This step requires the use of 4% PFA which is highly toxic, corrosive, and potential carcinogen. Proper caution should be taken when using this liquid. Also, protect samples from light.
    10. Wash the cells by adding 500 µl of PBS into the chamber and aspirate the solution gently.
    11. Repeat 3.1.9 step twice.
      NOTE: At this step, refill each vial immediately after removing the previous PBS.
    12. Stop the fixation by incubating with 500 µl of 50 mM NH4Cl in PBS for 10 min.
    13. Wash cells twice with PBS as described in step 3.1.10.
    14. Permeabilize cells by adding 250 µl binding buffer (0.1% saponin, 0.2% BSA in PBS) for 30 min at room temperature.
    15. Stain F-actin by adding fluorescently conjugated phalloidin (diluted 1:500 in binding buffer). Incubate cells for 1 hr at room temperature.
    16. Wash cells three times with PBS as described in step 3.1.10.
    17. Capture images using a confocal microscope (63X objective, and 402 nm and 488 nm laser) and analyze images using ImageJ16.
      NOTE: A successful particle binding is characterized by the presence of a phagocytic cup at the site where the particulate contact the phagocytic cell (Figure 1). See step 3.2.5.
  2. Phagocytosis Uptake Assay
    NOTE: This experiment is designed to monitor the complete internalization of fluorescently labeled particulates by phagocytes using confocal microscopy (Figure 2).
    1. Seed about 5 x 104 cells in a chamber slide so that they are 60-70% confluent at the time of the experiment. Alternatively, plate cells on cover slips (in 24- or 12-well format) or glass-bottom 96-well plates. Incubate cells overnight at 37 °C humidified incubator with 5% CO2.
      NOTE: Cells can be counted using hemocytometer or a similar technique.
    2. Keep the chamber slides (or plate) at 10 °C for 10 min.
      NOTE: Cooling is necessary in order to block endocytosis as well as unwanted phagocytosis, and subsequently to have a synchronized phagocytosis.
    3. Perform steps from 3.1.3 to 3.1.5
    4. Transfer the chamber slide to a 37 °C humidified incubator with 5% CO2, and incubate for different time points. Fix cells after 30, 60 and 90 min post infection. Observe C. albicans begin to form hyphae at 60 min post infection; phagocytes begin to show cell death (pyroptosis) after 90 min8.
      NOTE: This is a recommendation, and optimization is essential depending on the cell type and the particulate used.
    5. Perform steps from 3.1.7 to 3.1.15. Analyze images using ImageJ16.
      NOTE: a successful uptake is characterized by a complete internalization of a particulate inside the cytoplasm of a phagocyte (Figure 2). Staining the phagocytes with cell surface marker such as phalloidin helps to delineate the contour of cells. It is also essential to perform z-stacks in order to determine whether the particulate is bound to cell surface or completely internalized.
  3. Live Imaging of Phagocytosis
    NOTE: In this protocol we describe the use of confocal microscopy to capture the different stages of phagocytosis using fluorescently conjugated zymosan. We use the dendritic cell line DC2.4 that stably expresses mCherry-tagged F-actin8, a biosensor that shows the distribution of filamentous actin in living cells. Since phagocytosis is an actin-driven process the live imaging in this cell not only enables us to capture the movement and dynamics of F-actin network, but also to visualize the different phagocytic events within the living cells (Figure 3, Movie 1).
    1. Seed about 5 x 104 cells in a chamber slide at a concentration so that they are 60-70% confluent at the time of the experiment. Incubate cells overnight at 37 °C humidified incubator with 5% CO2.
      NOTE: Cells can be counted using hemocytometer or a similar technique.
    2. Keep the chamber slides on ice for 10 min.
      NOTE: Cooling is necessary in order to block unwanted uptake, and to have a synchronized phagocytosis.
    3. Perform steps from 3.1.3 to 3.1.5
    4. Pre-warm the microscope stage to 37 °C and equilibrate the chamber with 5% CO2. Wait 30-45 min for the temperature and the CO2 to stabilize before starting the imaging.
      NOTE: Since the CO2 and temperature levels are critical for phagocytosis, it is important to turn on the microscope heater prior to the experiment to equilibrate the environmental chamber.
    5. Place the chamber slide containing the cells in the microscope incubator enclosure equilibrated at 37 °C and 5% CO2.
    6. Perform live imaging17,18.
      NOTE: The settings for the laser power (gain, pinhole, etc.) can vary depending on the type of the microscope and fluorescent probe used. Therefore, we recommend consulting the manual of the microscope for optimal condition for your live imaging 17,18.
      1. Use confocal laser scanning microscope (and the associated software) for live imaging. Use 63X 1.4NA oil objective with a pinhole of 1-1.1 Airy units.
      2. To start the imaging, used the bright field to find a representative region on the chamber slide. Next, select the field by clicking the Position option on the software. To detect GFP in Track 1 used the filter set for 488 nm laser with a beam splitter at 582 nm, to detect wavelengths between 488 and 582 nm.
      3. In Track 2 select a filter set optimal for mCherry (RFP) using a beam splitter at 578 nm and detecting wavelengths between 578 and 600 nm. Use 488 nm and 578 nm lasers with 50% laser power and a gain output of 600-700. Obtain images every 30 sec for a total of 90 min.

Results

Microscope-based method to monitor the different stages of phagocytosis is presented. The different events during the phagocytosis of various fluorescent particulates by DC2.4 cells are shown. Using the techniques described here, we investigated the role of sphingolipids in the early stages of phagocytosis. For this purpose, DC2.4 dendritic cells genetically deficient in Sptlc2, the enzyme that catalyzes the first and rate-limiting step in the sphingolipid biosynthetic pathway, were used. As compared to wild type cells, ...

Discussion

Professional phagocytes, such as macrophages and dendritic cells, engulf and eliminate invading pathogens therefore making phagocytosis an important component of the host defense system. During this process phagocytes undergo extensive membrane reorganization and cytoskeleton rearrangement at their cell surface8,19,20. To better understand this dynamic process, visualization of the different stages of phagocytosis is essential. ...

Disclosures

The authors declare no conflicts of interest.

Acknowledgements

We thank Wendy Salmon and Nicki Watson of the Keck facility at the Whitehead Institute of MIT for imaging.

Materials

NameCompanyCatalog NumberComments
β-MercaptoethanolAppliChemA1108
Bovine serum albumin (BSA)Cell Signaling Technology 9998
DAPI (4',6-Diamidino-2-Phenylindole, Dilactate)ThermoFisherD3571
Dimethyl sulfoxide (DMSO)ThermoFisherBP-231-1
DMEM (Dulbecco’s Minimal Eagle’s medium)Gibco11965
PBS, 1x (Phosphate- Buffered Saline)Corning cellgro21-031-CV
Fetal Bovine serumSigma Aldrich12003C
FITC-coupled IgG-coated latex beadsCayman500290
L-Glutamine 200 mM (100x)ThermoFisher25030081
Paraformaldehyde Solution (4% in PBS)Affymetrix19943 1 LT
Penicillin-streptomycin (10,000 U/ml)ThermoFisher15-140-122
Phalloidin-Alexa Fluor 488ThermoFisherA12379
RAW 264.7 cellsATCCTIB-71
RPMI (Roswell Park Memorial Institute)Gibco61870
SaponinSigma AldrichS7900
Trypan blue solution (0.4% (w/v) in PBS)Corning cellgroMT25900CI
Trypsin-EDTA (1x) (0.05%)ThermoFisher25300054
Tween 20 Surfact-Amps Detergent SolutionThermoFisher 85114
Zymosan-Alexa Fluor 594ThermoFisherZ23374
Chambered 1.0 Borosilicate Coverglass system (8 chambers)ThermoFisher155361
Glasstic slide 10 with gridsHycor87144

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PhagocytosisConfocal MicroscopePathogenHost CellVirusFluorescently Conjugated ZymosanDC 2 4 CellsEndocytosisCytosisCell Culture MediumMultiplicity Of InfectionCentrifugationParaformaldehydeAmmonium Chloride

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