Assessment of Leishmania Virulence within Cultured Macrophages

Published: November 30, 2023

Abstract

Source: Sarkar, A. et al., Quantification of Intracellular Growth Inside Macrophages is a Fast and Reliable Method for Assessing the Virulence of Leishmania Parasites. J. Vis. Exp. (2018)

This video investigates Leishmania's virulence by treating macrophages with metacyclic promastigotes, resulting in the formation of intracellular amastigotes. The confirmation of Leishmania's virulence is achieved through nucleic acid fluorescent dye staining. This insight can contribute to the development of new therapies for leishmaniasis.

Protocol

All procedures involving animal models have been reviewed by the local institutional animal care committee and the JoVE veterinary review board.

1. Isolation and Differentiation of Bone Marrow-derived Macrophages (BMMs)

  1. Day 0: Sacrifice 4 – 6-week-old female C57BL/6 or BALB/c mouse in a CO2 chamber and confirm death via cervical dislocation. Ensure sterilization of scissors and forceps by keeping them soaked in 70% ethanol. Spray gloves with 70% ethanol to allow sterile handling throughout the bone marrow cell isolation process.
  2. Secure the sacrificed mouse to the dissection board by pinning its forelimbs and disinfecting it by spraying copiously with 70% ethanol.
  3. Make a small incision (about 1 cm) with scissors near the hip joint. Carefully insert scissors under the skin to separate the underlying muscle and cut the skin around the hip joint.    
    NOTE: The dissection board may be rotated to allow improved access to the hip joint.
  4. Carefully degloved skin from the leg by pulling towards the ankle and removing it. Cut the foot off at the ankle, being very careful to cut at or below the ankle joint to leave the tibia fully intact.       
    NOTE: The fibula at this stage is loosely attached and can be easily separated with the forceps.
  5. Manually locate the hip joint by manipulating the femur to identify the point of rotation. Carefully use scissors to sever the leg above the hip joint to leave the proximal head of the femur intact.
  6. Remove as much muscle and connective tissue as possible from the leg with scissors. Remove any remaining skin from the ankle and any excess bone material above the hip joint.
  7. Place the cleaned leg bones in sterile Roswell Park Memorial Institute RPMI supplemented with penicillin/streptomycin (1% final concentration) in a Petri dish on ice.
  8. Repeat steps 1.4 through 1.6 to isolate the tibia and femur from the other hind leg.
  9. Remove any remaining muscle and connective tissue from the bones soaking in RPMI using sterilized forceps and sterile #10 blade.
  10. Place bones on the Petri dish lid. Cut the tibia carefully with the blade immediately above the ankle joint to access the marrow. Remove the tibia from the rest of the leg by cutting immediately below the knee joint.
  11. Draw 10 mL sterile RPMI supplemented with penicillin/streptomycin (1% final concentration) into a 10-mL syringe and attach a 25G needle.
  12. Hold the tibia firmly with forceps, vertically over a 50-mL conical tube on ice. Use the syringe to gently inject approximately 5 mL RPMI into the end of the bone to flush the bone marrow out of the other end into the conical tube. Flush the bone marrow with a total of 10 mL RPMI until the bone turns white.    
    NOTE: After thorough flushing, the bone should turn white. If not, continue flushing to remove marrow. The distal end of the tibia may need to be trimmed back with the blade if it is too narrow to insert the needle.
  13. Cut the femur immediately above the knee joint and immediately below the hip joint to expose both ends of the bone to access the marrow. Flush bone marrow from the femur with a total of 10 mL RPMI in the same fashion as the tibia.
  14. Repeat cleaning and flushing steps 1.6 through 1.13 with the remaining bones and collect the bone marrow flushed cells in a single 50 mL conical tube
    NOTE: If a bone breaks at any point during dissection before bone flushing, do not use the marrow from this bone.
  15. Centrifuge the conical tube used to collect bone marrow flushed from all four bones for 10 min at 4 °C at 300 x g.
  16. Place 60 mL of sterile BMM medium (RPMI with a final concentration of 20% fetal bovine serum, FBS, 1% penicillin/streptomycin, 1.2 mM Na-pyruvate, 25 µg/mL human Macrophage Colony-Stimulating Factor (M-CSF) into a 175 cm2 cell culture flask with filter cap.
  17. Discard the supernatant following centrifugation and resuspend the cell pellet by gentle up and down pipetting using 5 mL of BMM medium from the flask.
  18. Transfer cell suspension to the culture flask and rinse the conical tube twice with BMM medium from the culture flask to ensure maximal cell recovery. Ensure cell suspension is thoroughly mixed into a medium, and distribute 30 mL from the initial 175 cm2 cell culture flask to a second 175 cm2 cell culture flask with a filter cap.
  19. Incubate both flasks containing 30 mL cell suspension each overnight at 37 °C, 5% carbon dioxide (CO2) to allow separation of any contaminating fibroblasts, resident macrophages, and other adherent cells.
  20. DAY 1: Transfer the supernatant containing undifferentiated bone marrow cells from flasks to 100 mm x 15 mm non-TC-treated polystyrene Petri dishes at approximately 10 mL/dish and incubate at 37 °C, 5% CO2. Discard the flasks.
  21. DAY 3 or 4: Add an additional 5 mL BMM medium (pre-warmed to 37 °C) to each Petri dish and continue incubation at 37 °C, 5% CO2.

2. Plating BMMs on Coverslips for Infection (DAY 7 or 8)

  1. Prepare 6-well tissue culture plates by placing four (4) sterile 12 mm glass coverslips (autoclaved and stored in a closed glass container) in the bottom of each empty well.    
    NOTE: Pick each sterile 12 mm coverslip up with an aspirating tip fitted to a vacuum line. Place coverslips into the wells without overlap, releasing them at the desired position by pinching the tube to interrupt the vacuum.
  2. Aspirate media (and any non-adherent cells) from Petri dishes coated with adherent bone marrow-derived macrophages and gently rinse adherent cells 2x with sterile Dulbecco's Phosphate buffered saline without calcium and magnesium chloride (PBS -/-) pre-warmed to 37 °C.
  3. Add dropwise, 5 mL sterile 1x PBS -/- with a final concentration of 1 mM ethylenediaminetetraacetic acid (EDTA) to each Petri dish and incubate for 5 min at 37 °C to detach adherent BMMs. Verify that the cells are detached using a microscope.
  4. Collect all detached cells suspended in 1x PBS -/- supplemented with 1 mM EDTA in a 50 mL conical tube. Rinse each dish 2x with 5 mL PBS -/- and add to the cell suspension pool.   
    NOTE: Cell suspension may be diluted with additional PBS -/- to protect macrophages from EDTA toxicity during the collection process.
  5. Centrifuge at 300 x g for 10 min at 4 °C. Discard supernatant and resuspend macrophages in 5 – 10 mL BMM medium by pipetting. Place resuspended cells on ice to prevent attachment to tubes and clumping.
  6. Count viable cells using Trypan blue exclusion in the hemocytometer.
    NOTE: To count BMM cells resuspended in 5 mL medium, a dilution mix of 25 µL cell suspension in 445 µL PBS -/- and 30 µL 0.4% Trypan blue solution typically allows easy quantification in a hemocytometer (taking into account a 20x dilution factor for the final calculation). Count only cells that did not get stained with Trypan blue (viable cells). The volume of cell suspension may be altered if this mixture is too concentrated or diluted. In general, the yield of BMM per preparation varies between 2 x 107 and 5 x 107 cells from a single mouse.
  7. Prepare the cell suspension in BMM medium at the desired plating concentration (5 x 105/mL) and disperse suspension to 6 well plates in 2 mL medium per well so that each well receives 1 x 10macrophages.         
    NOTE: This is a critical step that ensures every well gets an adequate number of macrophages to cover the coverslips uniformly. Check that the coverslips in wells are not overlapping or floating in the medium. If so, gently adjust with a sterile pipette tip.
  8. Incubate overnight at 37 °C, 5% CO2.

3. Purification of Infective Forms of Leishmania amazonensis

NOTE: Prepare Leishmania for infections- purify metacyclic promastigotes from stationary promastigote cultures, or differentiate promastigotes in culture into amastigote form using standard L. amazonensis axenic differentiation protocol.

  1. Purification of Leishmania metacyclic promastigotes using density gradient media(Materials)
    1. Prepare 40% stock solution of density gradient media in sterile, endotoxin-free water.
    2. Dilute density gradient solution in 10x M199 medium (without serum) to prepare 10% concentration in the M199 medium.
    3. Filter all solutions through a 0.22 µm filter.       
      NOTE: Stock solutions can be stored at 4 oC in darkness for no longer than 1 month.
    4. Add 2 mL of 40% density gradient media solution in the bottom of a 15-mL conical centrifuge tube.
    5. Layer 2 mL of 10% density gradient media solution in M199 on top of the 40% density gradient media layer carefully, using a Pasteur pipette to avoid any mixing between the two layers.
    6. Collect 1 x 109 parasites from stationary-phase culture by centrifugation at 1,900 x g for 10 min.
    7. Resuspend cells in 6 mL Dulbecco's Modified Essential Medium (DMEM).
    8. Layer 2 mL of the cell suspension directly on top of the 10% density gradient media layer, gently, using a Pasteur pipette to avoid mixing between layers.
    9. Centrifuge the gradient for 10 min at 1,300 x g at room temperature.
      NOTE: Due to differences in physical properties between Leishmania species, centrifugation conditions for each might have to be slightly adjusted to ensure maximum yield.
    10. Collect parasites (enriched in metacyclic promastigote form) from the band formed at the upper 10% density gradient media boundary (interface between the 0% and 10% density gradient media layers).
    11. Dilute parasites with one volume of DMEM and collect by centrifugation (1,900 x g for 10 min at room temperature).
    12. Resuspend in 500 µL DMEM medium and count in a hemocytometer to quantify yield.
  2. Generation of L. amazonensis amastigotes under axenic culture conditions (low pH / elevated temperature)
    1. Mix 5 mL of log-phase promastigote culture (pH 7.4 at 26 oC) with an equal volume of amastigote medium (pH 4.5), using 25 cm2 flasks (total 10 mL medium), and incubate at 26 °C overnight.
    2. Shift the flask from 26 °C to 32 °C.
    3. After 3 or 4 days, split culture 1:5 in amastigote media at 32 °C.
    4. Check the parasites in the next 3 – 4 days (maximum 7 days) to see if they are ready for use in infections.        
      NOTE: Healthy axenic amastigotes should have an oval shape, without visible flagella. Partially differentiated amastigotes have a large oval shape with short flagella. The culture should not have a lot of clumps – many clumps are an indication of non-growing, dying parasites. The amastigote culture can be split 1:5 and maintained for a maximum of 3 weeks.

4. Infection with L. amazonensis

  1. Dilute parasite suspensions according to desired multiplicity of infection (MOI) (usually 3-5 metacyclic promastigotes per macrophage [MOI of 1:3 or 1:5] and 1 amastigote per macrophage [MOI 1:1]). Add Leishmania in PBS -/- in a volume of 50 – 100 µL to each well already containing 2 mL medium.
  2. Incubate BMMs for 1 h with amastigotes and 3 h with metacyclic promastigotes at 34 oC for infection.      
    NOTE: Optimal infection temperature may vary by species.
  3. Following incubation, thoroughly wash away free parasites in each well 3x with 2 mL PBS -/- pre-warmed to 37 °C.      
    NOTE: Disperse PBS gently to ensure that coverslips do not float over each other. Gently swirl the plate and then aspirate out the liquid. Use a separate aspirating tip if using multiple strains of parasites to avoid cross-contamination.
  4. Fix 1 h or 3 h time-point samples by incubating each well with 1.5 – 2 mL of 2% PFA in PBS -/- for 10 min. Wash 3x with PBS -/-. Do not aspirate last wash and refrigerate plates containing coverslips in PBS until staining.
  5. Add 2 mL fresh BMM medium to each well on plates for further time points and incubate at 34 °C.
  6. Fix remaining time points as desired as described in step 4.3, and refrigerate plates until staining.

5. 4′,6-diamidino-2-phenylindole (DAPI) Staining and Coverslip Mounting

  1. Aspirate PBS from wells containing coverslips and add 1.5 mL PBS -/- with 0.1% non-ionic detergent. Incubate for 10 min at room temperature, followed by 3x wash with 2 mL PBS -/-.
  2. Add 1 mL PBS -/- with 2 µg/mL DAPI (diluted from 5 mg/mL stock solution in water) to wells containing coverslips and incubate for another 1 h at room temperature.
    NOTE: The incubation time with DAPI is critical for proper visualization of intracellular Leishmania parasites. Macrophage nuclei stain rapidly, due to their larger size and deoxyribonucleic acid (DNA) content but staining of nuclei of the intracellular parasites is slower. Thus, extending incubation time beyond what is required to visualize the BMM nuclei is necessary to allow DAPI to permeate through the parasite plasma membrane and the parasite nuclear membrane. With proper DAPI stain, the mitochondrial kinetoplast DNA near the flagellar pocket of the parasite can also be visualized, in addition to the nuclear DNA.
  3. Wash each well containing coverslips 3x with 2 mL PBS -/- and then lift and flip coverslips with forceps to place the cell side down and mount on glass microscope slides with a commercially available antifade mounting reagent.       
    NOTE: Coverslips are extremely fragile and need cautious handling. Avoid putting pressure on them, especially against the sidewall of the wells when lifting. Adding a few drops of PBS -/- reduces the surface tension between the coverslip and the well and facilitates the lifting process. A fine gauge needle may be used to assist in prying the coverslips from the bottom of the well. After placing a coverslip on the slide, gently press down with forceps to push out any air bubbles in the mounting media. If a coverslip is broken or has possibly flipped during the lifting process, do not remount; simply use the spare fourth coverslip.
  4. Refrigerate slides until quantification.

6. Infection Quantification

  1. Examine DAPI-stained slides under a fluorescence microscope by focusing on macrophages using a 100X objective lens with immersion oil (excitation at 358 nm; optimal emission at 461 nm).
    Ensure that the focus is on the layer of macrophages between the glass slide and coverslip.
  2. Quantify the number of macrophages (large nuclei stained with DAPI) and the number of smaller amastigote nuclei clustered around each macrophage nucleus (see Figure 1A, DAPI) for each field of vision, using a manual counter.
    NOTE: Amastigote nuclei may not all be visible in one plane of focus due to their small size. Count those that are visible when focused on macrophage nuclei, and then use fine focus to check for parasite nuclei in planes above and below the macrophage nuclei.
  3. Move to another field of vision to repeat quantification. Use a separate counter key to track the number of fields counted. Move through visual fields in parallel rows across each coverslip, to prevent counting overlap.
  4. Quantify a minimum of 200 macrophages per coverslip. Quantify each time-point of infection in triplicate (3 coverslips). Count the fourth coverslip if one of the previous ones is not suitable for counting due to coverslip overlap, poor mounting, glass breakage, etc.
    NOTE: If 200 macrophages cannot be counted on any one coverslip, count the spare fourth.
  5. Calculate infection rates as amastigotes/macrophage or amastigotes/100 macrophages and determine the percent infected macrophages from the raw quantification data.

Representative Results

Figure 1
Figure 1: A representative illustration of BMM infection with virulent axenic amastigotes (A) and non-virulent log-phase promastigotes (B) of L. amazonensis. Immunofluorescence images of macrophages isolated from BALB/c mice, 1 h and 48 h following infection. Infected macrophages were processed for immunofluorescence as described in the protocol. PV membranes were stained with rat anti-mouse Lamp1 monoclonal antibody (1:1,000 dilution) for 1 h, followed by 1 h incubation with anti-rabbit fluorescent IgG (1:500 dilution). Parasite staining was performed by incubating coverslips with mouse polyclonal antibodies generated against axenic L. amazonensis amastigotes, followed by anti-mouse IgG red dye (1:500 dilution) 6. All coverslips were further treated with DAPI for staining nuclei. (A) Formation of distinct PVs harboring multiple amastigotes at 48 h time point is characteristic of a successful Leishmania infection with axenic amastigotes. (B) The absence of distinct PV formation and replicating amastigotes at a 48 h time point typifies a lack of virulence in promastigotes from log-phase culture. Red indicates anti-Leishmania staining, green indicates anti-Lamp1, blue indicates DAPI-stained DNA, and yellow indicates a merge of anti-Lamp1 and DAPI stains. Bars, 5µm. This figure has been modified from Mittra, B. et al., 2013. Originally published in J. Exp. Med

Divulgations

The authors have nothing to disclose.

Materials

6 well cell culture plate Cellstar 657160
Adenine Acros Organics AC147440250
Aerosol Barrier Pipet Tips (100-1000 μL) Fisherbrand 02-707-404
Aerosol Barrier Pipet Tips (20-200 μL) Fisherbrand 02-707-430
Aerosol Barrier Pipet Tips (2-20 μL) Fisherbrand 02-707-432
Bard-Parker Rib-Back Carbon Steel Surgical Blade #10 Aspen Surgical 371110
BD Luer-Lok Tip 10 mL Syringe Becton Dickinson (BD) 309604
BD Precisionglide Needle, 25G  Becton Dickinson (BD) 305124
Cell Culture Dish 35 mm x 10 mm Cellstar 627 160
Cell Culture Flask Cellstar 660175
Cover Glasses: 12 mm circles Fisherbrand 12-545-80
DAPI (4',6-Diamidino-2-Phenylindole, Dihydrochloride) Invitrogen D1306
D-Biotin J.T. Baker C272-00
EDTA Sigma Aldrich EDS
Ethyl alcohol 200 proof Pharmco-AAPER 111000200
Falcon 100 mm x 15 mm non-TC-treated polystyrene Petri dish Corning 351029
Fetal Bovine Serum Seradigm 1500-500
Ficoll400 Sigma Aldrich F8016
Fluorescence Microscope Nikon E200
Goat anti-mouse IgG Texas red Invitrogen T-862
Goat anti-rabbit IgG AlexaFluor488 Invitrogen A-11034
Hemin Tokyo Chemical Industry Co. LTD H0008
HEPES (1M) Gibco 15630-080
Isoton II Diluent Beckman Coulter 8546719
L-Glutamine Gemini 400-106
Medium 199 (10X) Gibco 11825-015
Na pyruvate (100 mM) Gibco 11360-070
Paraformaldehyde Alfa Aesar 43368
Penicillin/Streptomycin Gemini 400-109
Phosphate Buffered Saline (-/-) ThermoFisher 14200166
Polypropyline conical Centrifuge Tubes 15 mL Cellstar 188 271
Polypropyline conical Centrifuge Tubes 50 mL Cellstar 227 261
ProLong Gold antifade reagent ThermoFisher P36930
Rat anti-mouse Lamp-1 antibody Developmental Studies Hybridoma Bank 1D4B
Recombinant Human M-CSF PeproTech 300-25
Reichert Bright-Line  Hemocytometer  Hausser Scientific 1492
RPMI Medium 1640 (1X) Gibco 11875-093
Triton X-100 Surfactant Millipore Sigma TX1568-1
Trypan Blue Sigma Aldrich T8154
Delicate Scissors, 4 1/2" VWR 82027-582
Dissecting Forceps, Fine Tip VWR 82027-386
Microscope Slides VWR 16004-368
Z1 Coulter Particle Counter, Dual Threshold Beckman Coulter 6605699

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Citer Cet Article
Assessment of Leishmania Virulence within Cultured Macrophages. J. Vis. Exp. (Pending Publication), e21792, doi: (2023).

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