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In This Article

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

Summary

The ability of inflamed endothelium to recruit leukocytes from flow is regulated by mesenchymal stromal cells. We describe two in vitro models incorporating primary human cells that can be used to assess neutrophil recruitment from flow and examine the role that mesenchymal stromal cells play in regulating this process.

Abstract

Stromal cells regulate the recruitment of circulating leukocytes during inflammation through cross-talk with neighboring endothelial cells. Here we describe two in vitro “vascular” models for studying the recruitment of circulating neutrophils from flow by inflamed endothelial cells. A major advantage of these models is the ability to analyze each step in the leukocyte adhesion cascade in order, as would occur in vivo. We also describe how both models can be adapted to study the role of stromal cells, in this case mesenchymal stem cells (MSC), in regulating leukocyte recruitment.

Primary endothelial cells were cultured alone or together with human MSC in direct contact on Ibidi microslides or on opposite sides of a Transwell filter for 24 hr. Cultures were stimulated with tumor necrosis factor alpha (TNFα) for 4 hr and incorporated into a flow-based adhesion assay. A bolus of neutrophils was perfused over the endothelium for 4 min. The capture of flowing neutrophils and their interactions with the endothelium was visualized by phase-contrast microscopy.

In both models, cytokine-stimulation increased endothelial recruitment of flowing neutrophils in a dose-dependent manner. Analysis of the behavior of recruited neutrophils showed a dose-dependent decrease in rolling and a dose-dependent increase in transmigration through the endothelium. In co-culture, MSC suppressed neutrophil adhesion to TNFα-stimulated endothelium.

Our flow based-adhesion models mimic the initial phases of leukocyte recruitment from the circulation. In addition to leukocytes, they can be used to examine the recruitment of other cell types, such as therapeutically administered MSC or circulating tumor cells. Our multi-layered co-culture models have shown that MSC communicate with endothelium to modify their response to pro-inflammatory cytokines, altering the recruitment of neutrophils. Further research using such models is required to fully understand how stromal cells from different tissues and conditions (inflammatory disorders or cancer) influence the recruitment of leukocytes during inflammation.

Introduction

Inflammation is a protective response to microbial infection or tissue injury that requires tight regulation of leukocyte entry into and exit from the inflamed tissue to allow resolution1,2. Cross-talk between endothelial cells (EC) that line blood vessels, circulating leukocytes and tissue-resident stromal cells is essential for coordinating this process3. However, uncontrolled recruitment of leukocytes and their ineffective clearance underpin the development of chronic inflammatory diseases4. Our current understanding of leukocyte recruitment in health and disease is incomplete and more robust models are needed to analyze this process.

The mechanisms supporting the recruitment of leukocytes from blood through vascular EC in post-capillary venules have been well described1,2,5. Circulating leukocytes are captured by specialized receptors (e.g., VCAM-1, E-selectin, P-selectin) which are up-regulated on inflamed endothelium. These transient interactions allow leukocytes to interact with surface bound chemokines and lipid-derived mediators (either endothelial or stromal in origin) that activate integrins expressed by leukocytes6-11. This in turn stabilizes adhesion and drives migration across the endothelium and into the tissue12-15. Within tissue, recruited leukocytes are subjected to stromal-derived agents that influence their motility, function and survival16,17. Growing evidence strongly suggests that signals received at each stage of the recruitment process conditions leukocytes for the next. However, our understanding of leukocyte recruitment remains incomplete and very little is known about the components shaping leukocyte movement within tissue.

In Birmingham we have developed several in vitro “vascular” models to study the recruitment of leukocytes from flow9,18,19. We now understand that vascular EC act as immediate regulators of leukocyte recruitment responding to changes in their local microenvironment. Specifically, tissue-resident stromal cells can actively regulate the inflammatory response, in part by conversing with neighboring vascular EC to influence their role in recruitment3. We have previously shown that various stromal cells modulate the ability of EC to support adhesion and migration of leukocytes in a tissue-specific manner, and that these effects become altered in chronic diseases13,16,20,21. Thus, stromal cells establish tissue ‘address-codes’ that define the context of each inflammatory response22. More recently, we have demonstrated that bone-marrow derived MSC (BMMSC) potently down-regulate the response of EC to cytokines, leading to a reduction in the recruitment of both neutrophils and lymphocytes23.

The mechanisms governing recruitment elucidated in vitro have largely used assays incorporating a single cell type (e.g., EC) or protein in isolation. However, these studies do not take into consideration the effects of the local tissue environment (i.e., the presence of stromal cells) on recruitment of leukocytes and their subsequent migration into the tissue. Here we describe two flow-based methods in which stromal cells, specifically mesenchymal stem cells (MSC), are co-cultured with EC23. Such models allow us to examine the effect of stromal cell on endothelial responses, in particular their ability to support leukocyte recruitment from flow.

Protocol

1. Isolation and Culture of Primary Human Endothelial Cells and Mesenchymal Stem Cells

  1. Isolation and culture of human umbilical vein endothelial cells (HUVEC):
    1. Put umbilical cord on a tray with paper towels and spray with 70% ethanol. Place in a tissue culture hood. Identify the vein and cannulate at both ends. Place a cable tie around the cannulated end to secure it.
    2. Wash out venous blood with PBS using a syringe. Fill syringe with air and pass through the vein to remove and discard the residual PBS.
    3. Thaw 10 mg/ml collagenase type Ia and dilute 1:10 in PBS (with calcium and magnesium chloride) to a final concentration of 1 mg/ml. Pass collagenase solution into the vein until both cannulae are filled. Close the clamps on cannulae at both ends.
    4. Cover the tray with tissue and spray with 70% ethanol. Place the cord into an incubator for 20 min at 37 °C and 5% CO2.
    5. Take the cord out of the incubator and tighten cable ties. Massage the cord gently for 1 min. Flush out the cell suspension with 10 ml PBS and collect in a 50 ml centrifuge tube.
    6. Fill syringe with air and pass through the vein to remove any residual PBS twice, collecting the PBS in a 50 ml centrifuge tube used in step 1.1.5. Centrifuge at 400 x g for 5 min at RT.
    7. Aspirate supernatant and resuspend pellet in 1 ml complete EC medium. EC medium consists of M199 supplemented with 35 µg/ml gentamicin sulphate, 10 ng/ml human epidermal growth factor, 1 µg/ml hydrocortisone, 2.5 μg/ml amphotericin B, and 20% fetal calf serum.
    8. Add 4 ml of EC medium and the EC suspension to a 25 cm2 flask. Change the medium on the following day and then every 2 days.
    9. EC exhibit a cobblestone-like morphology (Figure 1Ai). For adhesion assays, EC are generally seeded when they reach 100% confluence (see Section 1.4).
  2. Isolation of Wharton’s jelly mesenchymal stem cells (WJMSC) from human umbilical cords:
    1. Isolate Wharton’s jelly-derived MSC (WJMSC) from fresh umbilical cords or from cords that have already been used to isolate EC. Cut umbilical cord into 5 cm long pieces. Cut each piece longitudinally to reveal the blood vessels (2 arteries [white, rigid] and 1 vein [yellow, distended]).
    2. Using sterile scissors and forceps remove the blood vessels and discard. Cut all the tissue into 2 - 3 mm3 pieces. Using forceps place 2 - 3 mm3 pieces into a 50 ml centrifuge tube.
    3. Thaw 100 mg/ml stock collagenase type II and dilute 1:100 in 10 ml PBS to a final concentration of 1 mg/ml. Thaw 20,000 U/ml stock hyaluronidase and dilute 1:400 to a final concentration of 50 U/ml in the collagenase solution.
    4. Add enzymatic cocktail to the centrifuge tube containing the tissue fragments. Incubate the tissue fragments for 5 hr at 37 °C on a slow rotator.
    5. Dilute the cell suspension 1:5 in PBS. Place a 100 µm pore filter into a new 50 ml centrifuge tube. Pour the cell suspension onto the 100 µm pore filter.
      NOTE: Remaining tissue fragments will be retained on the filter and cells will be collected in the 50ml centrifuge tube.
    6. Discard the filter. Centrifuge the cell suspension at 400 x g for 10 min at RT. Aspirate supernatant and resuspend WJMSC pellet in 12 ml complete WJMSC culture medium (DMEM low glucose, 10% FCS and 100 U/ml penicillin + 100 µg/ml streptomycin mix).
    7. Seed all cells in a 75 cm2 tissue culture flask. Change the medium after 24 hr with 12 ml complete WJMSC culture medium. Replace medium every 2 - 3 days. Cells should reach 70 - 80% confluence within 2 weeks. Passage when WJMSC reach 70 - 80% confluence (see Section 1.4).
  3. Expansion of bone marrow-derived MSC (BMMSC):
    1. Isolate human bone marrow-derived MSC (BMMSC) as previously described24. Add 10 ml pre-warmed MSC growth medium (MSCGM) into a 15 ml centrifuge tube.
    2. Thaw a vial of p2 BMMSC by placing in a 37 °C water bath for 2 min. Add the BMMSC suspension to the centrifuge tube containing MSCGM. Mix well by pipetting.
    3. Centrifuge at 400 x g for 5 min at RT. Aspirate supernatant completely.
    4. Resuspend cells in 1 ml MSCGM and count the cells using a haemocytometer or a digital cell counter such as a cellometer.
    5. Seed cells into 75 cm2 culture flasks at a density of 5,000 - 6,000 cells per cm2 in 12 ml MSCGM. Change the medium after 24 hr with 12 ml MSCGM. Feed cells with 12 ml MSCGM every 2 - 3 days.
    6. Passage when BMMSC reach 70 - 80% confluence (see Section 1.4). Cells exhibit a fibroblastic morphology (Figure 1Aii).
  4. Detachment of EC and MSC:
    1. Aspirate medium from 25 cm2 culture flasks. Add 2 ml of 0.02% EDTA for approximately 2 min. Aspirate EDTA and add 2 ml trypsin (2.5 mg/ml). View under the microscope until the cells become round.
    2. Tap the flask to detach the cells. Inactivate the trypsin by adding 8 ml culture medium (dependent on cell type; EC medium for HUVEC, DMEM LG for WJMSC and MSCGM for BMMSC) to the culture flask and transfer suspension to a 15 ml centrifuge tube.
    3. Centrifuge at 400 x g for 5 min at RT. Aspirate supernatant and resuspend the pellet as described below.
      1. For passaging of MSC, resuspend pellet in 3 ml culture medium. Add 11 ml culture medium into three separate 75 cm2 culture flasks. Add 1 ml cell suspension to each culture flask (1:3 split). Passage WJMSC and BMMSC 3 times (p3) before use in co-culture assays.
      2. For seeding EC or MSC in adhesion assays – see Sections 2 and 3.
  5. Freezing MSC:
    1. At passage 3 detach MSC as described in Section 1.4. Aspirate supernatant and resuspend in 3 ml ice-cold CryoSFM. Pipette 1 ml aliquots of cell suspension into 1.5 ml ice-cold cryovials. Put cryovials in a freezing container.
    2. Store the container at -80 °C O/N. Transfer to liquid nitrogen. Thaw vial of MSC (follow steps 1.3.1 - 1.3.6). Resuspend MSC in 5 ml culture medium (choose appropriate medium for WJMSC or BMMSC) and seed into a 25 cm2 flask.

2. Establishing Endothelial-mesenchymal Stem Cell Co-cultures on Ibidi Microslides

  1. Trypsinize a confluent 25 cm2 flask of EC (~1.5 x 106 cells; as Section 1.4). Resuspend EC in 380 µl MSCGM (1 x 25 cm2 flask will seed two 6-channel Ibidi microslides (~1.25 x 105/channel), for adhesion assays all cell types are cultured in MSCGM). Add 30 µl of EC suspension to each channel (this will cover the growth area through capillary action). Incubate Ibidi microslide at 37 °C and 5% CO2 for 1 hr.
  2. Add 140 µl MSCGM to each channel and then aspirate it off. Repeat twice for a total of 3 washes. Add 140 µl MSCGM and place in the incubator at 37 °C and 5% CO2 for 24 hr.
  3. For co-cultures detach MSC (Section 1.4). Perform a cell count using a haemocytometer or a cellometer. Adjust the concentration of MSC to 1.5 x 105 cells/ml.
  4. Aspirate excess medium from the Ibidi channels (leaving only the growth area of the channel in medium). Add 30µl of MSC suspension to the Ibidi channels. Aspirate the medium that was ejected from the growth area of the channel and add another 30 µl of MSC suspension. Repeat once more and then place the Ibidi microslide in the incubator at 37 °C and 5% CO2 for 1 hr.
  5. Add 140 µl MSCGM to each channel and then aspirate it off. Repeat twice for a total of 3 washes. Add a final volume of 140 µl MSCGM to each channel and place in the incubator at 37 °C and 5% CO2 for 24 hr.
  6. Thaw 1 x 105 U/ml stock TNFα and dilute 1:1,000 in MSCGM to a final concentration of 100 U/ml (equivalent to ~10 ng/ml). Perform a serial dilution by diluting 100 U/ml TNFα by 1:10 in MSCGM to obtain 10 U/ml. Dilute 10 U/ml TNFα by 1:10 in MSCGM to obtain 1 U/ml.
  7. Treat channels with TNFα at 37 °C for 4 hr prior to the assay. Temperature fluctuations during the cytokine treatment will alter the patterns of neutrophil recruitment observed. Add fresh MSCGM to untreated channels.

3. Establishing Endothelial-Mesenchymal Stem Cell Co-cultures on Filters

  1. Detach WJ or BMMSC as described in Section 1.4. Resuspend the pellet in 1 ml MSCGM. Perform a cell count cells using a haemocytometer or a cellometer.
  2. Adjust volume so that the final concentration is 5 x 105 MSC in 500 µl of MSCGM.
  3. Using sterile forceps invert 6-well, 0.4 µm PET Transwell filters and place in a sterile box.
  4. Seed 5 x 105 MSC onto the outer surface of the filters. Incubate filters at 37 °C and 5% CO2 for 1 hr.
  5. Collect media from the outer surface of the filter. Count the number of non-adherent MSC in the media. Re-invert filters using sterile forceps and place in a matching 6-well plate containing 3 ml MSCGM.
  6. Add 2 ml of MSCGM onto the inner surface of the filter (Figure 1B). Place in an incubator at 37 °C and 5% CO2 for 24 hr. Trypsinize a confluent 25 cm2 flask of EC (Figure 1Ai; as Section 1.4).
  7. Resuspend EC in 8 ml MSCGM (1 x 25cm2 flask will seed four 6-well filters; ~5 x 105 EC/filter). Aspirate medium from the top and bottom of the porous filters. Add 3 ml fresh MSCGM into the lower chamber (underneath the filter). Add 2 ml EC suspension to the inner surface of each filter. Incubate for 1 hr at 37 °C and 5% CO2.
  8. Aspirate medium to wash off non-adherent EC and replace with fresh MSCGM. Set up parallel EC mono-culture filters by seeding cells on the inner surface without first seeding MSC. Incubate O/N at 37 °C and 5% CO2.
  9. Check that the EC monolayer is confluent and contains no gaps. Sub-confluent monolayers cannot be used for adhesion assays (Figure 1B).
  10. Treat the upper and lower chambers of the filters with 1, 10, or 100 U/ml TNFα (equivalent to ~10 ng/ml) at 37 °C for 4 hr prior to the assay (described in Section 2).

4. Isolation of Leukocytes

  1. Take venous blood from healthy volunteers and aliquot immediately into EDTA tubes. Invert tubes gently to mix.
  2. Layer 2.5 ml Histopaque 1077 onto 2.5 ml Histopaque 1119 in a 10 ml round bottomed tube. Layer 5 ml whole blood onto the Histopaque gradient. Centrifuge at 800 x g for 40 min at RT.
  3. Harvest peripheral polymorphonuclear neutrophils (PMN) at the interface of Histopaque 1077 and 1119 (above the erythrocyte layer). Place in a 10 ml round bottomed tube and make up to 10 ml with PBSA. Gently invert tube and centrifuge at 400 x g for 5 min at RT.
  4. Dilute 7.5% BSA solution 1:50 in 100 ml PBS (with calcium and magnesium chloride) to a final concentration of 0.15% (w/v; PBSA). Aspirate supernatant and resuspend in 10 ml PBSA. Centrifuge at 400 x g for 5 min at RT.
  5. Resuspend in 1 ml PBSA. Take a 20 µl aliquot of the cell suspension and add to 380 µl PBSA (1:20 dilution). Count cells using a haemocytometer or a cellometer. Dilute to the required concentration (1 x 106/ml for Transwell filters and Ibidi microslide) in PBSA. Maintain neutrophil suspension at RT until the assay.

5. Assembling the Flow System

  1. Set up the flow system as shown in Figure 1C. Turn on the heater and set to 37 °C. Attach a 20 ml syringe (remove the plunger) and a 5 ml syringe to a 3-way tap. Attach the tap to the Perspex chamber using Micropore tape.
  2. Measure and cut a long piece of silicon 2/4 mm (thick) tubing that is approximately the distance between the valve and the 3-way tap. Cut an 8 - 10 mm long piece of 1/3 mm (thin) tubing and insert into one end of the thick tubing. Attach the thick tubing side onto the 3-way tap.
  3. Connect the thin tubing end onto a port of the electronic 3-way microvalve. This is the “wash reservoir”. Cut a 6 - 8 mm long piece of thick and thin tubing.
  4. Insert the thin tubing into one end of the thick tubing. Attach the thick tubing end onto a 2 ml syringe (remove the plunger).
  5. Connect the thin tubing end of the 2 ml syringe onto a port on the electronic microvalve to make the “sample reservoir”. Connect the valve to the filter flow chamber by measuring and cutting a long piece of thin tubing that is the distance between the microvalve and the center of the microscope stage.
  6. For the microslide model, attach an 8 - 10 mm piece of thick tubing to the end of the thin tubing. Place an L shaped connector to the end of the thick tubing. This will connect to the microslide. For the filter model, attach an 8 - 10 mm piece of Portex Blue Line Manometer connecting tubing to the end of the thin tubing.
  7. Place the thin tubing end onto the microvalve. This is the common output for the wash and sample reservoirs. Fill reservoirs with PBSA. Prime tubing by flowing PBSA through them to remove any air bubbles.
  8. Attach Manometer tubing to a 29 mm (50 ml) glass syringe. Prime the syringe by filling with 10 ml PBSA. Invert the syringe so that the end connected to the tubing faces upwards and push out all air bubbles. Refill with 5 ml PBSA.
  9. For the microslide model only, attach a 10 - 12 mm piece of thick tubing to the end of the Manometer tubing leading to the glass syringe. Place an L shaped connector onto the end of the thick tubing. Place the glass syringe into a syringe pump for infusion/withdrawal.
  10. Calculate the refill flow rate (Q) required to generate the desired wall shear stress (τw in Pascal, Pa) of 0.1 Pa (Transwell filters) or 0.05 Pa (Ibidi microslides) using the following formulae:
    γw = (6.Q) / (w.h2)
    τ = n.γ
    Where w = internal width and h = internal depth of the flow channel. n = viscosity of the flowing solution; PBSA is n = 0.7 mPa.s. For the parallel plate filter flow chamber, the width (w) is 4 mm and the depth (h) is 0.133 mm. The depth of the chamber can vary slightly due to differences in the thickness of the Parafilm gasket used. For the Ibidi microslide, the width is 3.8 mm and the depth is 0.4 mm.
    NOTE: Due to differences in the dimensions of the flow channel, and capture dynamics we use different shear stresses for the microslide model compared to the filter model6.

6. Setting Up the Parallel Plate Flow Chamber Incorporating Filters

  1. Cut a piece of Parafilm (the same size as the glass coverslip) using a metal template. Cut out a 20 x 4 mm slot in the Parafilm (to create the flow channel) using a metal template. Use the gasket to mark the flow channel on the glass coverslip.
  2. Align the edges of the 6-well filter on the glass coverslip. Ensure that the filter covers the flow channel markings. Carefully cut out the filter using a type 10A scalpel.
  3. Carefully cover the filter with a Parafilm gasket, ensuring that the flow channel slot is in the middle of the filter (Figure 1D). Use a piece of clean tissue and push out any bubbles.
  4. Place the coverslip in the recess of the bottom plate of the Perspex flow chamber. Position the top Perspex plate over the top of the gasket and screw the plates together (Figure 1D).
  5. Turn the 3-way tap to allow wash buffer (PBSA) to flow through the valve. Connect Manometer tubing to the inlet port of the top Persex plate. Run PBSA through the flow channel to allow bubbles to pass through.
  6. Connect the Manometer tubing from the syringe pump into the outlet port of the Perspex plate. Set the syringe pump to refill and press run. Clean any PBSA that has dripped onto the upper plate of the chamber.
  7. Place the chamber on the stage of an invert phase-contrast microscope. Adjust focus to visualize the EC above the filters (Figure 1B).

7. Setting Up Microslides for Flow

  1. Place the microslide onto the stage of an invert phase contrast microscope. Connect the L shaped connector into the inlet port of a channel. Run PBSA through the flow channel.
  2. Place the L shaped connector from the syringe pump into the outlet port of the channel. Set the syringe pump to refill and press run. Clean any PBSA that has dripped onto the microslide. Adjust focus to visualize the EC monolayer.

8. Perfusion of Leukocytes Over Endothelial Cells

  1. Put 2 ml of purified neutrophils into the sample reservoir and leave to warm for 2 min. Wash the endothelium with PBSA for 2 min.
  2. Turn the valve ON to perfuse neutrophils over endothelium. Deliver the neutrophil bolus for 4 min. Turn the valve OFF and perfuse PBSA from the wash reservoir for the remainder of the experiment.
  3. Ensure that air bubbles do not pass through the flow channel at any point during the assay as this will disrupt the EC monolayer and cause detachment of adherent neutrophils.

9. Recording Neutrophil Capture and Behavior

  1. Record neutrophil recruitment either during neutrophil flow or post-perfusion.
  2. Make all digital recordings of at least 5 - 10 fields in the center of the flow channel. Identify the center of the channel by moving the objective to the edge of the channel at the inlet port and identifying the middle of the port.
    1. For recording during neutrophil flow, take images of a single field every 10 sec for 1 min. Move along the channel and record another field for 1 min. Repeat for duration of bolus.
    2. For recording post-perfusion, make 10 sec recording of 5 - 10 fields down the center of the flow channel for assessing leukocyte behavior (typically 2 min after the end of the neutrophil bolus). Take images every second within the 10 sec interval. This allows sufficient time for capture from flow and the behavior of adherent neutrophils to be analyzed.
    3. Record a single field containing at least 10 transmigrated neutrophils for 5 min, taking images every 30 sec. This can be used to calculate the velocity of migrated cells (either above or underneath the endothelium).
    4. Record another series of 10 sec fields (typically 9 min post-perfusion). This allows neutrophils time to migrate through the endothelial monolayer.
    5. Stop the syringe pump and remove the tubing. Disassemble the flow chamber and rinse the sample reservoir and tubing. Repeat for subsequent filters/microslide channels.

10. Analysis of Leukocyte Recruitment and Behavior

  1. Count the number of neutrophils in each field during the 10 sec recordings at the 2 min time point. All cells must be present in the first second field in order to be counted. Cells that are partially in the field on 2 sides (e.g., top/right hand border) of the field of view are included in the counts, as long as they remain in the field for the full 10 sec.
  2. Calculate the mean number of adherent neutrophil per field. Measure the length and width of the recorded field. Calculate the area of the field. Calculate how many fields there are in 1 mm2. Multiply the mean neutrophil count by the number of fields in 1 mm2.
  3. Calculate the total number of neutrophils perfused by multiplying the amount of neutrophils perfused (e.g., 2 x 106/ml*Q [e.g., 0.0999 ml/min for parallel plate flow chamber]) by the duration of the bolus (e.g., 4 min).
  4. Divide the neutrophil count/mm2 by the total number of neutrophils perfused to determine the total number of cells that have adhered (adherent cells/mm2 / 106 perfused).
  5. Assess whether the adherent neutrophils are rolling, firmly adherent or transmigrated (Supplementary Video 1 and 2).
    1. A rolling neutrophil is phase bright and will slowly move along the endothelial monolayer (1 - 10 µm/sec; Supplementary Video 1).
    2. Firmly adherent cells are phase bright and bound to the EC surface, either remaining stationary (i.e., not moving during recording) or have undergone shape change and are migrating over the EC surface (Figure 1Ei).
    3. A transmigrated neutrophil is phase dark and below the EC layer (Figure 1Eii).
  6. Calculate the percentage of adherent cells that are rolling, stationary and transmigrated. Alternatively, neutrophil behavior can be expressed as total cell numbers that exhibit the different behaviors by applying the same formula used to calculate total adhesion (as described in steps 10.6 - 10.7).
    1. Mark the leading edge of a rolling neutrophil. Mark the leading edge of the same cell at the end of the 10 sec sequence. Draw a line between the 2 points and measure the distance that the cell has travelled.
    2. Divide this value by the duration of the recording in which the cell is rolling (i.e., 10 sec). Try and select neutrophils that are in the field for the entire 10 sec interval.
  7. To calculate the velocity of neutrophils migrating over the surface (shaped changed phase bright) or underneath the endothelium (phase dark) use the 5 min recording (Supplementary Video 2).
    1. Draw an outline of migrated cells at the beginning of the sequence and track their movements throughout the sequence. Make note of the X and Y positions of the centroid at each 1 min interval for each cell. Subtract values of the X and Y position from the first image of the sequence from the values in the second image. This is based on Pythagoras’ theorem.
    2. Subtract the values from the second image from the third image. Do this for all images in the sequence. Square the X and Y values and add them together.
    3. Square root the resulting value. Calculate the velocity for each cell by averaging the velocities calculated at each minute interval. Track 10 migrated neutrophils and calculate the mean velocity.

Results

Initially, we analyzed the effect of stimulating EC with TNFα on the recruitment of neutrophils from flow using the Ibidi microslide model (Section 7 - 9). In the absence of TNFα, little if any neutrophils adhered to the endothelial monolayer (Figure 2A). This was expected, as untreated/resting EC do not express the necessary adhesion molecules (selectins) or chemokines to support binding25,26. In contrast, cytokine-stimulation significantly increased neutrophil adhe...

Discussion

Here we describe two in vitro “vascular” models for studying the recruitment of circulating neutrophils by inflamed endothelium. A major advantage of these models is the ability to analyze each step in the leukocyte adhesion cascade in order, as would occur in vivo. We have previously observed a dose-dependent increase in neutrophil adhesion to and transmigration through TNFα-stimulated EC9,29. We also describe how both models can be adapted to study the effects of stromal ce...

Disclosures

The authors declare that they have no conflicts of interest.

Acknowledgements

Umbilical cords were collected with the assistance of the Birmingham Women's Health Care NHS Trust. HMM was supported by an Arthritis Research UK Career Development Fellowship (19899) and Systems Science for Health, University of Birmingham (5212).

Materials

NameCompanyCatalog NumberComments
Collagenase Type IaSigmaC2674Dilute in 10 ml PBS to get a final concentration of 10 mg/ml. Store at -20 °C in 1 ml aliquots.
Dulbecco's PBSSigmaD8662With calcium and magnesium chloride. Keep sterile and store at RT.
1X Medium M199Gibco31150-022Warm in 37 °C water bath before use.
Gentamicin sulphateSigmaG1397Store at 4 °C. Add to M199 500 ml bottle.
Human epidermal growth factorSigmaE9644Store at -20 °C in 10 µl aliquots.
Fetal calf serum (FCS)SigmaF9665FCS must be batch tested to ensure the growth and viability of isolated EC. Heat inactivate at 56 °C. Store in 10 ml aliquots at -20 °C.
Amphotericin BGibco15290-026Potent and becomes toxic within a week so fresh complete HUVEC medium must be made up every week. Store at -20 °C in 1 ml aliquots.
HydrocortisoneSigmaH0135Stock is in ethanol. Store at -20 °C in 10 µl aliquots.
Collagenase Type IISigmaC6885Dilute stock in PBS to a final concentration of 100 mg/ml. Store at -20 °C in 100 µl aliquots.
HyaluronidaseSigmaH3631Dilute stock in PBS to a final concentration of 20,000 U/ml. Store at -20 °C in 100 µl aliquots.
100 µm cell strainer for 50 ml centifuge tubeScientific Lab Supplies (SLS)352360Other commercially available cell strainers (e.g. Greiner bio-one) can also be used.
DMEM low glucoseBioseraLM-D1102/500Warm in 37 °C water bath before use.
Penicillin/Streptomycin mixSigmaP4333Store at -20 °C in 1 ml aliquots.
25 cc tissue culture flaskSLS353109
75 cc tissue culture flaskSLS353136
Bone marrow mesenchymal stem cells vialLonzaPT-2501Store in liquid nitrogen upon arrival. Cells are at passage 2 upon arrival but are designated passage 0. Exapand to passage 3 and store in liquid nitrogen for later use.
Mesenchymal stem cell growth medium (MSCGM)LonzaPT-3001Warm in 37 °C water bath before use. For Cell Tracker Green staining use medium without FCS.
EDTA (0.02%) solutionSigmaE8008Store at 4 °C. Warm in 37 °C water bath before use.
Trypsin solutionSigmaT4424Store at -20 °C in 2 ml aliquots. Thaw at RT and use immediately.
CryovialsGreiner bio-one2019-02Keep on ice before adding before adding cell suspension.
Mr. Frosty Freezing ContainerNalgene5100-0001Store at RT. When adding cryovials with cells store at -80 °C for 24 hr before transfering cells to liquid nitrogen.
Ibidi u-Slide VI (0.4), T/C treated, sterileIbidiIB-80606Alternative models include glass capillaries, Cellix Biochips (www.cellixltd.com), BioFlux Plates (www.fluxionbio.com/bioflux/) and GlycoTech parallel plate flow chambers (http://www.glycotech.com/apparatus/parallel.html).
Cell tracker green dyeLife technologiesC2925Store in 5 µl aliquots at -20 °C. Dilute in 5 ml prewarmed (at 37 °C) MSCGM.
Cell counting chambersNexcelomSD-100Alternatively a haemocytometer can be used.
Cellometer auto T4 cell counterNexcelomAuto T4-203-0238
Tumor necrosis factor α (TNFα)R&D Systems210-TA-100Dilute stock in PBS to a final concentration of 100,000 U/ml. Store at -80 °C in 10 µl aliquots.
6-well, 0.4 µm PET Transwell filtersSLS353090
K2-EDTA in 10ml tubesSarstedtStore at RT.
Histopaque 1119Sigma11191Store at 4 °C. Warm to RT before use.
Histopaque 1077Sigma10771Store at 4 °C. Warm to RT before use.
10 ml round bottomed tubeAppleton WoodsSC211 142 AS
7.5% BSA Fraction V solutionLife technologies15260-037Store at 4 °C.
20 ml Plastipak syringesBD falcon300613
5 ml Plastipak syringesBD falcon302187
2 ml Plastipak syringesBD falcon300185
3M hypo-allergenic surgical tape 9 m x 2.5 cmMicropore1530-1Use to secure the syringe tap onto the wall of the perspex chamber.
Silicon rubber tubing, internal diameter/external diameter (ID/OD) of 1/3 mm (thin tubing)Fisher ScientificFB68854Cut silicon tubing to the appropriate size. All tubing leading directly to the electronic microvalve must be thin.
Silicon rubber tubing ID/OD of 2/4 mm (thick tubing)Fisher ScientificFB68855
Portex Blue Line Manometer tubingSmiths200/495/200Tubing leading to the syringe pump.
3-way stopcockBOC Ohmeda AB
Glass 50 ml syringe for pumpPopper Micromate550962Must be primed prior to use by removing any air bubbles.
Glass coverslipRaymond A Lamb26 x 76 mm coverslips made to order. Lot number 2440980.
Parafilm gasketAmerican National Can CompanyCut a 26 x 76 mm piece of parafilm using an aluminium template and cut a 20 x 4 mm slot into it using a scalpel 10a. Gasket thickness is approximately 133 µm.
Two perspex parallel platesWolfson Applied Technology LaboratorySpecially designed chamber consisting of parallel plates held together by 8 screws. The lower plate has a viewing slot cut out in the middle and a shallow recess milled to allow space for the coverslip, filter and gasket. The upper perspex plate has an inlet and outlet hole positioned over the flow channel.
Electronic 3-way microvalve with min. dead spaceLee Products Ltd.LFYA1226032HElectronically connected to a 12 volt DC power supply.
Syringe pump for infusion/withdrawal (PHD2000)Harvard Apparatus70-2001Set the diameter to 29 mm and refill (flow) rate.
L-shaped connectorLabhutLE876To attach to the inlet and outlet ports onto the Ibidi microslide channel.
Video cameraQimaging01-QIC-F-M-12-CConnected to a computer which enables digitall videos to be recorded.
Image-Pro Plus 7.0Media Cybernetics41N70000-61592For data analysis. Manually tag cells displaying the different behaviors. Track cells for analysis of rolling and migration velocities.
Refer to product datasheets for details on hazards of using the reagents described here.

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Keywords Endothelial CellsLeukocyte RecruitmentNeutrophil AdhesionMesenchymal Stem CellsIn Vitro Vascular ModelFlow based Adhesion AssayTNF alphaInflammatory Regulation

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