Preparation of Bead-supported Lipid Bilayers to Study the Particulate Output of T Cell Immune Synapses

Podsumowanie

Here we present the protocol for the stepwise reconstitution of synthetic antigen-presenting cells using Bead-Supported Lipid Bilayers and their use to interrogate the synaptic output from activated T cells.

Streszczenie

Antigen-presenting cells (APCs) present three activating signals to T cells engaged in physical contact: 1) antigen, 2) costimulation/corepression, and 3) soluble cytokines. T cells release two kinds of effector particles in response to activation: trans-synaptic vesicles (tSVs) and supramolecular attack particles, which transfer intercellular messengers and mediate cytotoxicity, respectively. These entities are quickly internalized by APCs engaged in physical contact with T cells, making their characterization daunting. This paper presents the protocol to fabricate and use Bead-Supported Lipid Bilayers (BSLBs) as antigen-presenting cell (APC) mimetics to capture and analyze these trans-synaptic particles. Also described are the protocols for the absolute measurements of protein densities on cell surfaces, the reconstitution of BSLBs with such physiological levels, and the flow cytometry procedure for tracking synaptic particle release by T cells. This protocol can be adapted to study the effects of individual proteins, complex ligand mixtures, pathogen virulence determinants, and drugs on the effector output of T cells, including helper T cells, cytotoxic T lymphocytes, regulatory T cells, and chimeric antigen receptor-expressing T cells (CART).

Wprowadzenie

The immunological synapse (IS) is a pivotal molecular structure formed at the interface of cells engaged in physical contact that facilitates the regulated exchange of juxtracrine information. Different ISs have been described in the literature, and a growing body of evidence suggests these molecular hubs are a conserved feature of cellular networks. Various immune cells, including B cells, natural killer cells, dendritic cells, macrophages, and T cells, exchange information via the assembly of short-lived contacts¹. Multiomic studies are advancing the understanding of novel subsets of leukocytes and stromal cells driving pathogenic cellular networks and expressing surface proteins with unknown functions. As synthetic APCs, BSLBs allow the direct investigation of the functional role of individual proteins in the integration of activating signals, namely antigens and costimulation/corepression, by T cells and the resulting release of effector particles referred to as signal four.

This paper describes the protocols and critical technical points to consider while using BSLBs to mimic the surface composition of model APCs. The protocols for the quantitative measurement of immune receptors and other surface proteins on APCs are presented along with the protocol for the reconstitution of synthetic APCs containing these measured quantities. Then, the steps required for coculturing T cells and BSLB are presented along with the protocol for the quantitative measurement of trans-synaptic particle transfer using flow cytometry. Most remarkably, BSLBs facilitate studying a plasma membrane-derived population of tSVs termed synaptic ectosomes (SEs). T-cell antigen receptor-enriched (TCR⁺) SEs are shed in response to TCR triggering² and efficiently captured by BSLBs³, representing an excellent readout to assess the agonistic properties of antigens and the modelled membrane composition. CD63⁺ exosomes and supramolecular attack particles (SMAPs) are also released by stimulated T cells and captured by BSLBs. They can be used as additional readouts of activation and the resulting exocytic and lytic granule secretion by T cells. The mobilization of exocytic vesicles to the interacting pole of the T cell also facilitates the directional release of cytokines, such as IL-2, IFN-γ, and IL-10 in response to activation^4,5,6,7,8. Although T-cell released cytokines can also be detected on BSLBs, a more dedicated study is currently under development to validate the quantitative analysis of cytokine release at the immunological synapse.

To interrogate how specific membrane compositions influence T cells' synaptic output requires defining the physiological density of the target membrane component. Flow cytometry-based quantifications of cell surface proteins are an essential step in this protocol and require: 1) the use of antibodies with known numbers of fluorochromes per antibody (F/P), and 2) benchmark beads providing a standard reference for interpolating fluorochrome molecules from measured mean fluorescence intensities (MFIs).

These benchmark standards consist of five bead populations, each containing an increasing number of equivalent soluble fluorochromes (MESFs), which span the dynamic range of arbitrary fluorescence detection. These standard populations yield discrete fluorescence peaks, facilitating the conversion of arbitrary fluorescence units into MESFs by simple linear regression. The resulting MESFs are then used alongside antibody F/P values to calculate the average number of bound molecules per cell (or BSLB in later steps). The application of estimated cell surface areas to the average number of detected molecules then enables the calculation of physiological densities as molecules/µm². This quantification protocol can also be adapted to the measurement of protein densities on T cells and the biochemical reconstitution of membrane compositions mediating the formation of homotypic T cell synapses (i.e., T-T synapses⁹). If needed, the valency of antibody binding can be further estimated by using recombinant targets labeled with known numbers of fluorochromes per molecule. Then, the antibody-binding valency can be calculated for the same BSLB population by simultaneously comparing the number of bound fluorescent proteins and quantification antibodies (using two different quantification fluorochromes and MESF standards).

The reconstitution of APC membranes requires the assembly of supported lipid bilayers (SLBs) on silica beads¹. Liposome stocks containing different phospholipid species can be harnessed to form a versatile lipid-bilayer matrix, enabling the anchoring of recombinant proteins with different binding chemistry (the preparation of liposomes is detailed in ¹⁰). Once the physiological density (or densities) of the relevant ligand "on cells" is defined, the same flow cytometry protocol is adapted to estimate the concentration of recombinant protein needed to coat BSLBs with the target physiological density. Two different anchoring systems can be used either in combination or separately.

First, SLB containing a final 12.5 mol% of Ni²⁺-containing phospholipids is sufficient to provide approximately 10,000 His-tag binding sites per square micron¹⁰ and works well to decorate BSLBs with most commercially available proteins whose physiological densities do not exceed this maximum loading capacity. The second loading system harnesses biotin-containing phospholipids (as mol%) to load biotinylated anti-CD3e Fab (or HLA/MHC monomers) via streptavidin bridges. The combination of these two BSLB decoration methods then enables the flexible tailoring of BSLBs as synthetic APCs. For highly complex APC surface compositions, the mol% of phospholipids and proteins can be increased to load as many proteins as the question at hand requires. Once the working concentrations of proteins and mol% of biotinylated phospholipids are defined, BSLBs can be assembled to interrogate the synaptic output of T cells with multiparametric flow cytometry.

Access restricted. Please log in or start a trial to view this content.

Protokół

1. Measurement of cell surface protein densities with quantitative flow cytometry

1. Prepare 0.22 µm-filtered human flow cytometry buffer (hFCB) by adding EDTA (to a final 2 mM concentration) and human AB serum (to a final 10%) to sterile phosphate-buffered saline (PBS), pH 7.4 (see Table 1). Filter the solution using a 0.22 µm pore filter unit to remove serum impurities and store at 4 °C.
2. Recover the cells and sediment them by centrifugation at 300 × g for 5 min at room temperature (RT).
3. Wash the cells twice with PBS. In each washing step, resuspend the cells in PBS to the original volume (before centrifugation) and spin down at 300 × g for 5 min at RT.
4. Count trypan blue-stained cell suspensions in a hemocytometer¹¹. Alternatively, count cells using electric current exclusion. For the latter, follow the CASY-TT manufacturer's instructions (see the Table of Materials).
   NOTE: The CASY-TT cell counter allows the determination of percent viable cells, cell size, and cell volume.
5. Calculate the volume of PBS containing 1:1,000 dilution of Fixable Viability Dye eFluor 780 or similar (see the Table of Materials) required to resuspend the cells to a staining concentration of 10⁷ cells/mL.
6. Resuspend the cells using the viability dye-PBS solution and incubate on ice for 30 min.
7. Remove the viability dye by adding one volume of ice-cold hFCB. Spin down at 300 × g for 5 min at 4 °C.
   NOTE: From now onwards, keep the cold chain unbroken.
8. Wash the cells with hFCB containing 1:50 dilution of Fc Receptor Blocking Solution (see the Table of Materials). Bring the volume to a final concentration of 10⁷ cells/mL and incubate for an additional 15 min to achieve efficient FcgR blocking.
9. Distribute 100 µL of the cell suspension (i.e., 10⁶ cells) per well of a U-bottom or V-bottom 96-well plate. Keep the cells on ice and protected from light (cover with aluminum Foil).
10. Prepare an antibody master mix in hFCB by defining the optimal antibody concentrations for each fluorochrome-conjugated antibody, and most importantly, for those antibodies used to determine surface protein densities. For example, for quantification of ICAM-1 expression on tonsillar cell populations, as shown in Figure 1, prepare a mix containing 1:200 dilutions of anti-CD4, anti-CD19, and anti-CXCR5 together with saturating concentrations of an anti-ICAM-1 antibody with known AF647 fluorochromes per antibody (i.e., 10 µg/mL, which was defined by independent antibody titration experiments).
11. As additional controls, prepare an antibody master mix containing the relevant antibody isotype controls (at the same effective concentrations as their counterparts conjugated with the same fluorochromes for background subtraction), i.e., use 10 µg/mL of a relevant AF647 isotype control.
    NOTE: In the example above, such an isotype control is used to subtract background fluorescence from the true ICAM-1 signal on cells.
12. When quantifying protein densities on cell subsets present at low frequencies within tissues, prepare fluorescence minus one (FMO) controls containing all staining antibodies except for the markers of interest (see further details in ¹²).
13. Spin down the 96-well plate containing the cells at 300 × g for 5 min at 4 °C, discard the supernatant, and resuspend the cells in 50 µL of either the quantification antibody master mix or the isotype antibody master mix.
14. Incubate the cells for at least 30 min at 4 °C and 400 rpm using a plate shaker. Protect the plates from light (cover with aluminum foil).
15. Wash the cells three times using hFCB and centrifuge at 300 × g for 5 min at 4 °C.
16. Resuspend the cell pellet using 200 µL of PBS (i.e., to a final concentration of 5 × 10⁶ cells/mL).
17. For acquisition:
    1. If using a standard BD FACS Loader, transfer the samples to 5 mL polystyrene round-bottom tubes (see the Table of Materials).
    2. If using High-throughput Samplers (HTS, also referred to as plate readers), proceed immediately to step 1.19.
18. Before proceeding with the data acquisition for the MESF standards, check the fluorescence intensity linearity maximum and minimum limits for the quantification channels.
19. Before compensation, acquire data for the MESF standards, ensuring both the dimmest and brightest populations fall in the linear range of measurement.
20. Acquire the compensation samples. Keep the photomultiplier tube (PMT) voltage values for the quantification channels unchanged to preserve the dynamic range of detection. Perform slight adjustments in the PMT voltage of other channels before calculating the compensation matrixes.
21. Calculate and apply compensation.
22. Acquire and save a minimum of 2 × 10⁴ total MESF beads for each of the quantification channels.
23. Select the population of single cells based on their side and forward light scattering areas (SSC-A and FSC-A, respectively, as shown in Figure 1A (i)), followed by the selection of events inside the time continuum (Figure 1A (ii)) and low for time of flight (W) in both FSC and SSC as compared to their heights (i.e., FSC-W/FSC-H, followed by SSC-W/SSC-H gating as shown in Figure 1A (iii) and (iv), respectively). Define a final single-event gate containing events with proportional FSC-A versus FSC-H distribution (Figure 1A (v)).
24. Acquire control samples (Isotype-labeled and FMO controls).
25. Acquire samples and record until a minimum of 10,000 target cells have been acquired.
    NOTE: the robust determination of average molecular densities requires the analysis of several donors across independent experiments. This is crucial when analyzing either cell subsets found in reduced frequencies or derived from scarce biological material (e.g., from human tissue biopsies).
26. Wash the cytometer running for 5 min with a FACS cleaning solution followed by 5 min of ultrapure water before shutting down the instrument. If using the HTS, follow the options under the tab HTS and Clean Plate program.
    NOTE: To reduce sample-to-sample carryover, activate sit (sampler) flush or high-throughput sampler wash options, which will automatically wash the cytometer between tubes or wells. Before starting the acquisition, run ultrapure water for 10 min at a high flow rate to remove any unwashed biological contaminants from the cytometer sample line.
27. Export the Flow Cytometry Standard (FCS) files.

2. MESF overcorrected mean (or median) fluorescence intensity (MFI) regression analyses

1. Open the flow cytometry analysis software and load the experiment FCS files. Select the population of beads based on their side and forward light scattering areas (SSC-A versus FSC-A), as shown in Figure 1A (i).
2. Control data quality by checking the distribution of single events over time, as indicated in step 1.24.
   NOTE: Bubbles create gaps in the distribution of events over time; this typically appears at the beginning of acquisition using the HTS. Avoid selecting events flanking gaps in the acquisition time as these add measurement errors due to optical aberrations.
3. Focus on the single events.
   1. Cells
      1. Identify single cells first based on their SSC-A and FSC-A distribution (Figure 1A (i)), followed by events low for W in the sequential gates FSC-W/FSC-H (singlets-1, Figure 1A panel (iii)) and SSC-W/SSC-H (singlets-2; Figure 1A panel (iv)). Define an additional singlets-3 gate by selecting events with proportional FSC-A and FSC-H (Figure 1A, panel (v)). Finally, identify live cells as those negative for the fixable viability dye.
   2. MESF beads
      1. Follow the same singlets-1 to singlets-3 discrimination as in step 2.3.1.1 (Figure 1B, panels (i) to (v)). Identify each of the MESF populations (blank, 1, 2, 3, and 4) based on their fluorescence intensity levels (see Figure 1B, panel (vi)).
4. Extract the MFI of MESF fractions blank and 1 to 4.
5. Generate corrected MFI (cMFI) values for MESF fractions 1 to 4 by subtracting the MFIs of the blank bead population from each fraction.
6. Calculate the line of best fit for the relationship between cMFIs and the MESF values provided by the vendor (independent variable, being fraction blank equal to zero).
7. Extract the slope (b in the equation below) of the linear regression of MESF over cMFI (Figure 1B panel (viii) shows a regression in which y = a + bx; with a = 0).
8. Extract the median (for bimodal fluorescence distributions) or mean (for normal or log-normal fluorescence distributions) fluorescence intensities from the populations of interest (TFH and B cells in Figure 1A panel (vii)).
9. As in steps 2.5-2.7, extract the MFI values from isotype-labeled control cells.
10. If the F/P of isotype controls is the same as the quantification antibodies, correct the MFIs of stained cells by subtracting the MFIs from Isotype-labeled cells.
11. If the F/P of the isotypes differs from those of quantification antibodies, extract the MESF from the isotypes by dividing the MFIs of isotype-labeled cells with the slope calculated in step 2.7. Subtract Isotype MESF from quantification MESF before estimating bound quantification antibodies.
12. Divide the MESF by the F/P of the quantification antibodies to estimate the number of bound molecules per cell (Molec._cell as shown in the flow diagram of Figure 1C).
13. Divide the number of bound molecules with the estimated cell surface area (CSA (µm²)) to extract the density of proteins as molec./µm² (Figure 1C). Refer to the representative results section for more details.

3. Functional phospholipid species to use in the calibration of proteins coating BSLBs

1. Use 0.4 mM DOPC (1,2-dioleoyl-sn-glycero-3-phosphocholine) as the major component of the lipid matrix forming the supported lipid bilayer. Dilute all other lipids species in this DOPC solution.
2. Use between 0.2 and 1 mol% of 0.4 mM DOPE (1,2-Dioleoyl-sn-glycero-3-phosphoethanolamine) conjugated to dyes, including ATTO 390, 488, or 565 (see the Table of Materials), to generate BSLBs with intrinsic fluorescence.
   NOTE: The intrinsic fluorescence of BSLBs facilitates the identification of single BSLBs and single cells in synaptic transfer experiments.
3. Use 12.5 mol% of 0.4 mM DGS-NTA(Ni) (1,2-dioleoyl-sn-glycero-3-[(N-(5-amino-1-carboxypentyl) iminodiacetic acid) succinyl]) to anchor His-tagged proteins. Keep the mol% of DGS-NTA(Ni) constant and perform 2-fold titrations of the His-tagged proteins starting with 100 nM as the highest concentration. Leave one condition with no protein as a negative control for absolute quantifications.
   NOTE: Accessory signals and adhesion molecules, such as ICAM-1, are designed with a 12-His tag to increase the affinity of the protein for DGS-NTA(Ni).
4. Use Biotinyl Cap PE (1,2-dioleoyl-sn-glycero-3-phosphoethanolamine-N-(cap biotinyl)) to anchor biotinylated proteins via biotin-streptavidin-biotin bridges. Use a 5-fold serial titration of 0.4 mM Biotinyl Cap PE covering between 10 mol% and 0 mol% (as negative control). Keep the concentration of streptavidin and biotinylated proteins constant (200 nM) in both calibration experiments and the reconstitution of synthetic APCs for synaptic transfer experiments.
   NOTE: The regression analyses of empirical densities of biotinylated proteins over the final mol% of Biotinyl Cap PE in the lipid matrix (also containing DGS-NTA(Ni) to anchor His-tagged proteins) will define the mol% to be used to reconstitute target densities of antigen.

4. Preparation of supplemented HEPES buffered saline containing 1% serum albumin

NOTE: Supplemented HEPES-buffered saline containing 1% human serum albumin (HBS/HSA) or 1% bovine serum albumin (HBS/BSA) is required in the washing and protein loading steps of BSLBs (Table 1). Prepare a 10x HBS stock solution and the working buffer as fresh as possible; keep refrigerated and use within one month. While BSA is a cheaper alternative to HSA, it provides efficient blockage of Ni-chelating lipids¹³ and is recommended for high-throughput experiments.

1. Prepare a 10x stock buffer solution of supplemented HBS containing 200 mM HEPES, 7 mM Na₂HPO₄, 1400 mM NaCl, 50 mM KCl, 60 mM glucose, 10 mM CaCl₂, and 20 mM MgCl₂.
   NOTE: Dissolving MgCl₂ is highly exothermic and a burn hazard. Add this salt slowly and on a large volume of solvent. Avoid preparing concentrated solutions (i.e., 1 M) of these salts as they tend to precipitate over time, making their precise addition to the working buffer difficult.
2. Filter the 10x solution using a 0.22 µm filter unit and keep it sterile at 4 °C.
3. For 500 mL of HBS/has, take 50 mL of the supplemented 10x HBS solution, adjust the pH to 7.4 if needed, and make up the volume to 483.4 mL with ultrapure water.
4. Add 16.6 mL of 30% HSA solution to the 483.4 mL of HBS, pH 7.4.
5. For 500 mL of HBS/BSA, dissolve 5 g of BSA in HBS and incubate at 37 °C for 30 min. Then, mix gently at RT by inverting the bottle periodically until there are no visible protein crystals or clumps.
6. Filter the resulting solution from step 4.5 using a 0.22 µm filter unit (see the Table of Materials) and store it at 4 °C.

5. Protein density calibrations on BSLBs

1. Before taking the 5.00 ±0.05 µm diameter non-functionalized silica beads, mix the stock solution well and resuspend any big clumps of beads sedimented on the bottom of the flasks.
   NOTE: Silica beads tend to sediment quickly, which might lead to counting errors. Mix vigorously by pipetting up and down half of the maximum volume of a P1000 micropipette.
2. Dilute 1 µL of bead solution in 1,000 µL of PBS, count the beads using a hemocytometer chamber, and calculate their concentration per mL.
   NOTE: Trypan blue staining is not needed for visualizing silica beads.
3. Calculate the volume of silica beads needed for 5 × 10⁵ final BSLBs per point of the titration.
4. Transfer the required volume of silica beads to a sterile 1.5 mL microcentrifuge tube.
5. Wash the silica beads three times with 1 mL of sterile PBS, centrifuge the beads for 15 s on a benchtop microcentrifuge at RT (at fixed rpm).
   NOTE: When removing the washing solution, avoid disturbing the bead pellet. A small buffer column will not affect the spreading of the liposomes composing the liposome master mix as these are also in PBS.
6. Prepare three volumes of the liposome master mix to assemble the BSLB on the washed silica beads (e.g., if the initial total volume of silica beads is 20 µL, prepare a minimum of 60 µL of the liposome master mix).
7. For Biotinyl Cap PE mol% titrations
   1. Prepare the lipid master mixes containing 5-fold dilutions of Biotinyl Cap PE.
      1. Dilute the 0.4 mM Biotinyl Cap PE mol% in a 100% DOPC matrix.
      2. Mix each Biotinyl Cap PE mol% titration point at a 1:1 (vol:vol) ratio with a solution of 0.4 mM 25% DGS-NTA(Ni) such that a final 12.5 mol% of Ni-containing lipids is present in all titrations.
         NOTE: The 12.5 mol% (vol:vol%) of Ni-containing lipids represent the mixed lipid composition of BSLBs on which His-tagged proteins can also be tested in parallel calibrations. For example, since all liposome stocks are prepared at the same molar concentration, to reach the target mol% mixture in 200 µL of final liposome mix, simply mix 100 µL of 25 mol% of Ni-containing DGS-NTA with 100 µL of 100 mol% DOPC.
   2. Transfer 5 × 10⁵ washed silica beads to 1.5 mL microcentrifuge tubes, such that one Biotinyl Cap PE mol% titration point is assembled per tube.
   3. Add the Biotinyl Cap PE mol% titration master mixes to the washed silica beads and gently mix by pipetting up and down half of the total volume. Avoid forming bubbles, which in excess destroy the lipid bilayer.
   4. Add Argon (or Nitrogen) gas on the tube containing the now-forming BSLBs to displace air and protect the lipids from oxidation during mixing.
   5. Add Argon to the 0.4 mM lipid stocks before storage and manipulate using a sterile technique.
      NOTE: Connect a small tubing to the Argon/Nitrogen gas cylinder. Before adding gas to the tubes, adjust the gas cylinder regulator so that the pressure is set no higher than 2 psi. Connect a sterile pipette tip to the outlet tubing to direct the gas stream inside the liposome stock for 5 s and quickly close the lid. In the case of lipid stocks, seal the tube's lid with paraffin film before storing it at 4 °C.
   6. Move the BSLBs to a vertical, variable-angle laboratory mixer (see the Table of Materials) and mix for 30 min at RT using an orbital mixing of 10 rpm.
      NOTE: This step will prevent the sedimentation of beads during the formation of the supported lipid bilayer.
   7. Spin down the beads by centrifuging for 15 s at RT on a benchtop minicentrifuge, and then wash three times with 1 mL of HBS/HSA (BSA) to remove excess liposomes.
   8. Block the formed BSLBs by adding 1 mL of 5% casein or 5% BSA containing 100 µM of NiSO₄ to saturate NTA sites and 200 nM streptavidin to coat all biotin-anchoring sites on the BSLBs uniformly. Mix gently by pipetting up and down half of the total volume and incubate in the vertical mixer for no longer than 20 min at RT and 10 rpm.
   9. Spin down the BSLBs by centrifuging for 15 s at RT on a benchtop minicentrifuge, and then wash three times with 1 mL of HBS/HSA (BSA) buffer.
      NOTE: Keep washed beads vertically with a small volume of wash buffer covering the BSLBs. Avoid the dehydration of the BSLBs as air will destroy the lipid bilayer.
8. For the titration of His-tagged proteins on 12.5 mol% of DGS-(Ni) NTA-containing BSLBs
   1. Prepare three volumes of liposome master mix containing a final 12.5 mol% of DGS-NTA(Ni).
   2. Use the liposome master mix to resuspend the washed silica beads and gently mix by pipetting up and down half of the total volume. Avoid forming bubbles, which in excess damage the lipid bilayer.
   3. Add Argon (or Nitrogen) gas on the tube containing the now-forming BSLBs to displace air and protect the lipids from oxidation during mixing.
   4. Add Argon to the 0.4 mM lipid stocks before storage and manipulate using a sterile technique.
   5. Move the BSLBs to the vertical mixer and mix for 30 min at RT using orbital mixing at 10 rpm.
   6. Spin down the beads by centrifuging for 15 s at RT on a benchtop minicentrifuge, and then wash three times with 1 mL of HBS/HSA (BSA) to remove excess liposomes.
   7. Block the formed BSLBs by adding 1 mL of 5% casein (or 5% BSA) containing 100 µM of NiSO₄ to saturate NTA sites on the BSLBs. Mix gently and incubate in the vertical mixer for no longer than 20 min at RT and 10 rpm.
   8. Wash three times using HBS/HSA (BSA) to remove the excess blocking solution.
   9. In a new U-bottom 96-well plate prepare 2-fold serial dilutions of the proteins.
      1. Prepare a starting concentration of 100 nM for the protein of interest in a total volume of 200 µL of HBS/HSA (BSA) buffer, distribute 100 µL of this solution in the first column, and the remaining 100 µL on top of column #2 containing 100 µL of HBS/HSA (BSA) buffer.
      2. Continue by serially transferring 100 µL from column #2 to column #3 and repeat as necessary to cover all titration points. Leave the last column of the series with no protein, as this will be used as the blank reference for quantification.
   10. Resuspend the prepared BSLBs in a volume such that 5 × 10⁵ BSLB are contained in 100 µL of HBS/HSA (BSA) buffer.
   11. Transfer 100 µL of the BSLB suspension to wells of a second U-bottom 96-well plate, such that each well receives 5 × 10⁵ BSLBs.
   12. Spin down the second plate containing BSLBs for 2 min at 300 × g and RT and discard the supernatant.
   13. Transfer the 100 µL volumes from the protein titration plate to the plate containing the sedimented BSLBs. Mix gently, avoid excess bubble generation while pipetting, and incubate for 30 min at RT and 1,000 rpm using a plate shaker. Protect from light with aluminum foil.
   14. Wash the plate three times with HBS/HSA (BSA) buffer using sedimentation steps of 300 × g for 2 min at RT.
   15. If the recombinant protein used in the calibration is directly conjugated to fluorochromes and has known F/P values, proceed to step 5.8.20.
   16. If the recombinant protein used in the calibration is unlabeled or conjugated to fluorochromes or no MESF bead standard is available, use Alexa Fluor 488 or 647-conjugated antibodies with known F/P values to stain the protein-coated BSLB.
   17. Stain with saturating concentrations of quantification antibodies.
       NOTE: Depending on the target expression level, these range between 5 and 10 µg/mL.
   18. Stain for 30 min at RT and 1,000 rpm using a plate shaker. Protect from light using aluminum foil.
   19. Wash twice with HBS/HSA (BSA) buffer and once with PBS using sedimentation steps of 300 × g for 2 min at RT.
       NOTE: Use PBS, pH 7.4 to resuspend the washed BSLBs before acquisition. Do not use buffers containing protein, as this leads to the formation of bubbles during the automatic mixing of samples with high-throughput samplers.
   20. Acquire the MESF standards, making sure the brightest peaks remain in the linear detection range for the quantification detector (channel), as shown in Figure 1B (vii).
   21. Acquire the samples manually or using HTS. If using the latter, resuspend BSLBs in 100 µL of PBS and acquire 80 µL using a flow rate between 2.5 and 3.0 µL/s, a mixing volume of 100 µL (or 50% of the total volume if the resuspension volume is less), a mixing speed of 150 µL/s, and five mixes to ensure BSLBs are monodispersed.
   22. Export the FCS files.
   23. Focus on single events for the analyses (Figure 2A), as doublets or triplets will introduce error in the determination. Use nested identification of single events as indicated in protocol step 1.2.3.
   24. Measure the MFI of each MESF fraction (1-4) and subtract the MFI of blank beads to extract corrected MFIs (cMFI).
   25. Perform a linear regression analysis to extract the slope (b) of MESF over the cMFI calculated for MESF standards, which will be used in step 5.33.
   26. Extract the MFI of each titration point and subtract the MFI of beads without protein to obtain cMFIs.
   27. Divide the cMFIs with the slope calculated in step 5.31 to extract the MESF bound to BSLBs for each titration point.
   28. Divide MESF bound to BSLBs by the F/P value of the quantification antibody to extract the average number of molecules bound per BSLB.
   29. Using the diameter of the BSLBs (5.00 ± 0.05 µm), extract the bead surface area (SA = 4pr²) to calculate the final densities of protein (molec./µm²) per titration point (protein concentration).
   30. Perform a new regression analysis of protein concentration over protein density to calculate the slope (b) of the line of best fit.
       NOTE: The concentration of 12.5 mol% of DGS-NTA(Ni) confers a maximum anchoring capacity of approximately 10,000 molec./µm^{2 10} without inducing the nonspecific activation of T cells or affecting the lateral mobility of the SLBs.

6. Performing synaptic transfer experiments between T cells and BSLBs

1. Before running the synaptic transfer experiment
   1. Acquire non-fluorescent BSLBs, BSLBs with fluorescent lipids, unstained cells (or compensation beads; see the Table of Materials), and single-color-stained cells (or compensation beads) to identify the instrument's fluorescence spectrum interactions. Focus on those detectors with high spillover spreading to redesign the polychromatic panel, increase sensitivity, and reduce the measurement error on critical detectors (see ¹⁴).
   2. Titrate the detection antibodies to find the optimal concentration, enabling positive events detection without compromising the detection of negatives.
      NOTE: Repeat this step whenever there is an antibody lot change as the F/P values and brightness vary from batch to batch.
   3. Optional: Optimize the PMT voltages by acquiring the sample at different voltage ranges (i.e., a voltage walks) to find the PMTs leading to optimal signal over noise (i.e., separation of negatives and positives while ensuring the signal of the brightest population remains in the linear range).
2. Measurement of T-cell output transfer to BSLBs
   1. Prepare supplemented RPMI 1640 (herein R10 medium) containing 10% of heat-inactivated fetal bovine serum (FBS), 100 µM non-essential amino acids, 10 mM HEPES, 2 mM L-glutamine, 1 mM sodium pyruvate, 100 U/ml of penicillin, and 100 µg/mL of streptomycin. Use R10 medium to culture and expand T cells.
   2. On day 1, isolate T cells from peripheral blood or leukoreduction system (LRS) chambers. Use immunodensity cell isolation and separation kits (see the Table of Materials) for enrichment of human CD4⁺ and CD8⁺ T cells.
   3. Seed the cells at a final concentration ranging between 1.5 and 2.0 × 10⁶ cells/mL, using 6-well plates with no more than 5 mL total per well.
   4. Activate T cells using a 1:1 ratio of human T cell activation (anti-CD3/anti-CD28) magnetic beads (see the Table of Materials) and add 100 IU of recombinant human IL-2 to support cell proliferation and survival.
   5. On day 3, remove the activating magnetic beads using magnetic columns (see the Table of Materials). Ensure that magnetic beads remain attached to the sides of the tube before recovering the cells for additional washing steps.
   6. Wash the magnetic beads once more with 5 mL of fresh R10 medium, mix well, and put them back in the magnet . Recover this volume and mix with the cells recovered in step 6.2.5.
   7. Resuspend the cells to 1.5-2 × 10⁶ cells/mL in fresh R10 containing 100 U/mL of IL-2. Replenish medium after 48 h, making sure that the last addition of IL-2 is 48 h before the day of experimentation (days 7 to 14 of culture).
   8. On the day of the synaptic transfer experiment, prepare the Synaptic Transfer Assay medium (see Table 1) by supplementing Phenol Red-free RPMI 1640 medium with 10% FBS, 100 µM non-essential amino acids, 2 mM L-glutamine, 1 mM sodium pyruvate, 100 U/ml of penicillin, and 100 µg/mL of streptomycin. Do not include recombinant human IL-2.
   9. Count cells using either trypan blue staining or electric current exclusion and resuspend them to a final concentration of 2.5 × 10⁶ cells/mL in medium. If excessive cell death is observed (>10%), remove dead/dying cells using a mixture of polysaccharide and sodium diatrizoate (see the Table of Materials) as follows:
      1. Layer 15 mL of cell culture on top of 13 mL of the polysaccharide-sodium diatrizoate solution.
      2. Centrifuge for 1,250 × g for 20 min at RT with minimum acceleration and deacceleration. Collect the cell layer (cloud) in the interface between the medium and the polysaccharide-sodium diatrizoate solution.
      3. Wash the cells at least twice with prewarmed Synaptic Transfer Assay medium (prepared in step 6.2.7).
      4. Count and resuspend the cells to a final concentration of 2.5 × 10⁶/mL using Synaptic Transfer Assay medium. Coculture 100 µL of this cell suspension with BSLBs (see step 6.2.15).
   10. Calculate the number of BSLBs needed for the experiment; consider all the different protein master mixes and antigen titrations to be tested (either biotinylated HLA/MHC-peptide monomers or monobiotinylated anti-CD3ε Fab).
   11. Assemble the BSLBs by following the same steps from protocol section 5 but this time, combine all the titrations of proteins and lipids required to reconstitute a complex APC membrane (Figure 3A). Keep the same vol: vol relationships between the initial silica beads volume and the volume of protein mix used during calibrations, as well as times and temperatures used in the loading of BSLBs. For example, if 0.5 µL of silica beads/well and 100 µL/well of protein mix were used for the initial calibration, maintain 5:1,000 vol:vol ratios to prepare the BSLBs to be cocultured with T cells.
   12. Once BSLBs have been loaded with the protein mix of interest, wash the BSLBs twice with HBS/HSA (BSA) to remove excess unbound proteins. Use sedimentation speeds of 300 × g for 2 min at RT in each washing step and discard the supernatants.
   13. Resuspend the 5 × 10⁵ BSLBs per well in 200 µL.
   14. Transfer 100 µL per well to a new U-bottom 96-well plate to make a duplicate, such that the final amount of BSLB per well is 2.5 × 10⁵.
   15. Spin down the BSLBs at 300 × g for 2 min and RT and discard the supernatant.
   16. Resuspend the BSLBs using 100 µL of T cell suspension; mix gently to prevent the formation of bubbles.
   17. Incubate the cocultures for 90 min at 37 °C.
       NOTE: Alternatively, cells and beads can be resuspended in HBS/HSA (BSA) buffer instead of Phenol-Red free RPMI for the coculture. In this case, the incubation must be performed in a non-CO₂ incubator as this gas will rapidly acidify the buffer in the absence of bicarbonate.
   18. Cool down the BSLB-T cell cocultures by first incubating the cells at RT for a minimum of 15 min. Protect them from light.
   19. Centrifuge the cells for 5 min at 500 × g and RT; discard the supernatant.
   20. Resuspend the cells in RT 2% BSA-PBS (Ca²⁺ and Mg²⁺-free) for blocking. Place the cells on ice for 45 min. Protect from light.
   21. While incubating the cells, prepare the antibody master mix using ice-cold 0.22 µm-filtered 2% BSA in PBS as a staining buffer, which will provide extra blocking.
       NOTE: Some batches of antibodies conjugated to Brilliant Violet dyes tend to bind to BSLBs nonspecifically. Blocking with 5% BSA-PBS helps to reduce this noise. From now on, make sure to keep the cold chain unbroken.
   22. Spin down the cocultures at 500 × g for 5 min and 4 °C. Before discarding the supernatants, briefly make sure the pellet is present by inspecting the bottom of the 96-well plate using a backlight.
   23. Using a multichannel pipette, resuspend the cells in the staining master mix containing optimized antibody concentrations.
       NOTE: Use pipette tips with no filter to prevent the generation of bubbles and errors in the distribution of staining volumes.
   24. Include isotype-labeled cells and BSLBs, fluorescent and non-fluorescent BSLBs, and cells and BSLBs stained alone. Respect the total number of events per well for all controls (i.e., only BSLBs containing 5 × 10⁵ BSLB/well, and only cell controls containing 5 × 10⁵ cells/well to avoid a relative increase of antibodies per stained event).
   25. Mix gently by pipetting up and down half of the volume and incubate for 30 min on ice. Protect from light.
   26. Wash the cells and BSLBs twice using ice-cold 2% BSA-PBS, pH 7.4, and sedimentation steps of 500 × g for 5 min at 4 °C. Resuspend the washed cocultures in 100 µL of PBS and acquire immediately.
   27. If fixation is needed, fix using 0.5% w/v of PFA in PBS for 10 min, wash once, and keep in PBS until acquisition. Protect from light.
   28. Before compensation, acquire MESF standards, ensuring both the dimmest and brightest populations fall in the linear range of measurement.
   29. Acquire compensation samples, calculate compensation, and apply the compensation matrix (link) to the experiment.
   30. Acquire and save a minimum of 2 × 10⁴ total MESF standards for each of the quantification channels.
   31. For acquisition using high-throughput samplers, set instrument acquisition to standard, set sample acquisition to 80 µL (or 80% of total volume), sample flow rate between 2.0 and 3.0 µL/s, sample mixing volume of 50 µL (or 50% of the total volume to avoid bubble formation during mixing), sample mixing of 150 µL/s, and mixing per well between 3 and 5.
   32. Acquire a minimum of 1 × 10⁴ single BSLBs per sample (refer to Figure 3B panels (i)-(vi) for the reference gating strategy).
   33. Wash the cytometer running for 5 min a cleaning solution followed by 5 min of ultrapure water before shutting down the instrument. If using the HTS, follow the options under the tab HTS and the Clean option.
   34. Export FCS files.

7. Measuring the synaptic transfer of particles to BSLB

1. Open the experiment FCS files. Select the population of cells and BSLBs based on their side and forward light scattering areas (SSC-A versus FSC-A), as shown in Figure 3B (i).
2. Select the events within the continuous acquisition window (Figure 3B (ii)).
3. Focus on the single events of both cells and BSLB; identify single cells first based on low W in the sequential gates FSC-W/FSC-H (singlets-1, Figure 3B panel (iii)) and SSC-W/SSC-H (singlets-2; Figure 3B panel (iv)). Define an additional singlets-3 gate by selecting events with proportional FSC-A and FSC-H (Figure 3B, panel (v)).
4. Extract the MFI of MESF fractions blank and 1 to 4 and from single cells and MESF for each experiment sample.
5. Generate corrected MFI (cMFI) values for MESF fractions 1 to 4 by subtracting the MFI of the blank bead population from each fraction.
6. Generate cMFIs for single BSLBs and cells (refer to Figure 3C panel (i)).
7. Use the signal from BSLB stained with isotype control antibodies to correct the MFI of BSLB stained with antibodies against the relevant T cell markers. Use cMFI to calculate the normalized synaptic transfer percent (NST%) by using the equation shown in Figure 3C panel (ii).
8. If interested instead in the particles specifically transferred in response to TCR triggering, subtract the signal from null BSLBs from the MFI of agonistic BSLBs. Use this cMFI to calculate the TCR-driven NST% by using the equation shown in Figure 3C panel (ii).
9. If interested in determining the total number of molecules transferred as particle cargo across the T cell-BSLB interface, acquire MESF benchmark beads using the same instrument settings and acquisition session for T cell-BSLB cocultures.
10. Analyze MESF bead populations and extract their cMFIs as indicated in protocol steps 5.8.15 to 5.8.17. Calculate the slope of the line of best fit for the regression analysis of MESF over cMFI.
11. Use the calculated slope to extract the number of MESF deposited on BSLBs. Use cMFIs calculated using either isotype controls or null BSLB as blanks to extract the number of MESF transferred specifically to stimulating BSLBs.
12. Calculate the number of molecules of markers transferred to BSLBs by dividing the calculated (average) MESFs per BSLB by the F/P value of the quantification antibody.

Access restricted. Please log in or start a trial to view this content.

Wyniki

FCM for absolute protein quantification on the cell surface
The reconstitution of BSLBs presenting physiological densities of ligands requires the estimation of total protein densities on the modeled cell subset. To reconstitute BSLBs, include any relevant ligand expected to play a role in the signaling axis of interest alongside proteins supporting the adhesion and functional interaction between BSLB and cells, such as ICAM-1 and costimulatory molecules, e.g., CD40, CD58, and B7 receptors (CD80 an...

Access restricted. Please log in or start a trial to view this content.

Dyskusje

BSLBs are versatile tools for studying the particulate output of T cells stimulated with model APC membranes. The flexibility of the method allows the reconstitution of complex and reductionist membrane compositions to study the effects of ligands and their signals on the secretion of tSVs and supramolecular attack particles and their components. We have tested this technology on various T cells, including preactivated TH, CTL, Tregs, and CART¹⁵. This protocol also works for the measurement of syn...

Access restricted. Please log in or start a trial to view this content.

Materiały

Name	Company	Catalog Number	Comments
1,2-dioleoyl-sn-glycero-3-[(N-(5-amino-1-carboxypentyl)iminodiacetic acid)succinyl] (nickel salt)	Avanti Polar Lipids	790404C-25mg	18:1 DGS-NTA(Ni) in chloroform
PIPETMAN L Multichannel P8x200L, 20-200 µL	Gilson	FA10011
1,2-dioleoyl-sn-glycero-3-phosphocholine	Avanti Polar Lipids	850375C-25mg	18:1 (Δ9-Cis) PC (DOPC) in chloroform
1,2-Dioleoyl-sn-glycero-3-phosphoethanolamine (DOPE) ATTO 390	ATTO-TEC	AD 390-165	DOPE ATTO 390
1,2-Dioleoyl-sn-glycero-3-phosphoethanolamine (DOPE) ATTO 488	ATTO-TEC	AD 488-165	DOPE ATTO 488
1,2-Dioleoyl-sn-glycero-3-phosphoethanolamine (DOPE) ATTO 565	ATTO-TEC	AD 565-165	DOPE ATTO 565
1,2-dioleoyl-sn-glycero-3-phosphoethanolamine-N-(cap biotinyl) (sodium salt)	Avanti Polar Lipids	870273C-25mg	18:1 Biotinyl Cap PE in chloroform
200 µL yellow tips 10 x 96 Tips, Stack	Starlab	S1111-0206
5 mL polystyrene round-bottom tubes	Falcon®	352052
5.00 ± 0.05 µm non-functionalized silica beads	Bangs Laboratories Inc.	SS05003
96 Well Cell Cultture Plate U-bottom with Lid, Tissue culture treated, non-pyrogenic.	Costar®	3799	For FCM staining and co-culture of BSLB and cells.
96 Well Cell Cultture Plate V-bottom with Lid, Tissue culture treated, non-pyrogenic.	Costar®	3894	For FCM staining of cells or beads in suspension.
Alexa Fluor 488 NHS Ester (Succinimidyl Ester)	Thermo Fisher Scientific, Invitrogen™	A20000
Alexa Fluor 647 NHS Ester (Succinimidyl Ester)	Thermo Fisher Scientific, Invitrogen™	A37573 and A20006
Allegra X-12R Centrifuge	Beckman Coulter		For normal in tube staining of biological samples for FCM
Aluminum Foil	Any brand		For protecting cells and BSLBs from light
anti-human CD154 (CD40L), clone 24-31	BioLegend	310815 and 310818	Alexa Fluor 488 and Alexa Fluor 647 conjugates, respectively.
anti-human CD185 (CXCR5) Brilliant Violet 711, clone J252D4	BioLegend	356934	For quantitative FCM analysis of tonsillar cells as shown in Fig. 1E
anti-human CD19 Brilliant Violet 421, clone HIB19	BioLegend	302234	For quantitative FCM analysis of tonsillar cells as shown in Fig. 1E
anti-human CD2, clone RPA-2.10	BioLegend	300202	Labeled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human CD2, clone TS1/8	BioLegend	309218	Brilliant Violet 421 conjugate.
anti-human CD252 (OX40L), clone 11C3.1	BioLegend		Alexa Fluor 647 conjugate
anti-human CD28, clone CD28.2	eBioscience	16-0289-85	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human CD317 (BST2, PDCA-1), clone 26F8	ThermoFisher Scientific, invitrogen	53-3179-42	Alexa Fluor 488 conjugate, we found this clone to be cleaner than clone RS38E.
anti-human CD38, clone HB-7	BioLegend	356624	Alexa Fluor 700 conjugate
anti-human CD38, clone HIT2	BioLegend	303514	Alexa Fluor 647 conjugate
anti-human CD39, clone A1	BioLegend		Labeled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human CD4 Brilliant Violet 650, clone OKT4	BioLegend	317436	For quantitative FCM analysis of tonsillar cells as shown in Fig. 1E
anti-human CD4, clone A161A1	BioLegend	357414 and 357421	PerCP/Cyanine5.5 and Alexa Fluor 647 conjugates, respectively
anti-human CD4, clone OKT4	BioLegend	317414 and 317422	PE/Cy7 and Alexa Fluor 647 conjugates, respectively
anti-human CD40, clone 5C3	BioLegend	334304	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human CD40, clone G28.5	BioLegend		Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human CD45, clone HI30	BioLegend	304056 and 368516	Alexa Fluor 647 and APC/Cy7 conjugates
anti-human CD47, clone CC2C6	BioLegend	323118	Alexa Fluor 647 conjugate
anti-human CD54 (ICAM-1), clone HCD54	BioLegend	322702	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human CD63 (LAMP-3), clone H5C6	BioLegend	353020 and 353015	PerCP/Cyanine5.5 and Alexa Fluor 647 conjugates, respectively
anti-human CD73, clone AD2	BioLegend	344002	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human CD80, clone 2D10	BioLegend	305216	Alexa Fluor 647 conjugate
anti-human CD81, clone 5A6	BioLegend	349512 and 349502	PE/Cy7 conjugate and labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester), respectively.
anti-human CD82, clone ASL-24	BioLegend	342108	Alexa Fluor 647 conjugate
anti-human CD86, clone IT2.2	BioLegend	305416	Alexa Fluor 647 conjugate
anti-human CD8a, clone HIT8a	BioLegend	300920	Alexa Fluor 700 conjugate
anti-human CD8a, clone SK1	BioLegend	344724	Alexa Fluor 700 conjugate
anti-human HLA-A/B/C/E, clone w6/32	BioLegend	311414 and 311402	Alexa Fluor 647 conjugate and Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human HLA-DR, clone L243	BioLegend	307656 and 307622	Alexa Fluor 488 and Alexa Fluor 647 conjugates, respectively.
anti-human ICAM-1, clone HCD54	BioLegend	322702	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human ICOS, clone C398.4A	BioLegend	313516	Armenian Hamster IgG
anti-human ICOSL, clone MIH12	BioLegend	329611	Alexa Fluor 647 conjugate
anti-human ICOSL, clone MIH12	eBioscience	16-5889-82	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human LFA-1, clone TS1/22	BioLegend	Produced in house	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human OX40, clone Ber-ACT35 (ACT35)	BioLegend	350018	Alexa Fluor 647 conjugate
anti-human PD-1 , clone EH12.2H7	BioLegend	135230 and 329902	Alexa Fluor 647 conjugate and Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human PD-L1, clone 29E.2A3	BioLegend	329702	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human PD-L2, clone 24F.10C12	BioLegend	329611	Alexa Fluor 647 conjugate
anti-human PD-L2, clone MIH18	BioLegend	345502	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
anti-human TCRab, clone IP26	BioLegend	306712 and 306714	Alexa Fluor 488 and Alexa Fluor 647 conjugates, respectively.
antti-human CD156c (ADAM10), clone SHM14	BioLegend	352702
antti-human CD317 (BST2, Tetherin), clone RS38E	BioLegend	348404	Alexa Fluor 647 conjugate
Armenian Hamster IgG Alexa Fluor 647 Isotype control, clone HTK888	BioLegend	400902	Labelled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
BD Cytometer Setup and Tracking beads	Becton Dickinson & Company (BD)	641319	Performance track of instruments before quantitative FCM
BD FACSDiva	Becton Dickinson & Company (BD)	23-14523-00	Acquisition software
Bovine Seum Albumin	Merck, Sigma-Aldrich	A3294
CaCl2, Calcium chloride	Merck, Sigma-Aldrich	C5670	anhydrous, BioReagent, suitable for insect cell culture, suitable for plant cell culture, ≥96.0%
Casein from bovine milk, suitable for substrate for protein kinase (after dephosphorylation), purified powder	Merck, Sigma-Aldrich	C5890
Dynabeads Human T-Activator CD3/CD28	ThermoFisher Scientific, Gibco	11132D
DynaMag-2	ThermoFisher Scientific, Invitrogen™	12321D	For the removal of Dynabeads Human T-Activator CD3/CD28 in volumes less than 2 mL
DynaMag™-15	ThermoFisher Scientific, Invitrogen™	12301D	For the removal of Dynabeads™ Human T-Activator CD3/CD28 in volumes less than 15 mL
Fetal Bovine Serum Qualified, One Shot	ThermoFisher Scientific, Gibco	A3160801	Needs heat inactivation for 30 min at 56 oC
Ficoll-Paque PLUS	Cytiva, GE Healthcare	GE17-1440-02	Sterile solution of polysaccharide and sodium diatrizoate for lymphocyte isolation
Fixable Viability Dye eFluor 780	eBiosciences	65-0865-14	For the exclusion of dead cells during analyses
FlowJo	Becton Dickinson & Company (BD)	Version 10.7.1	Analysis software
Grant Bio MPS-1 Multi Plate Shaker	Keison Products	MPS-1	For the mixing of either cells during stainings or BSLBs during staning or protein loading (as an alternative to orbital agitation)
HEPES Buffer Solution (1 M)	ThermoFisher Scientific, Gibco	15630-056
HEPES, N-(2-Hydroxyethyl)piperazine-N′-(2-ethanesulfonic acid), 4-(2-Hydroxyethyl)piperazine-1-ethanesulfonic acid.	Merck, Sigma-Aldrich	H4034	For preparation of HBS/HAS or HBS/BSA buffer. BioPerformance Certified, ≥99.5% (titration), suitable for cell culture
HERACell 150i CO2 incubator, 150 L, Electropolished Stainless Steel	ThermoFisher Scientific	51026282	For culturing and expanding purified CD4+ and CD8+ T cells.
Hula Mixer® Sample Mixer	ThermoFisher Scientific, Life Technologies	15920D	Vertical, variable-angle laboratory mixer used for the mixing of BSLBs and lipid master mix, blocking solutions, protein master mix and small scale antibody stainings.
Human Serum Albumin, 30% aqueous solution	Merck, Sigma-Aldrich	12667-M
Human TruStain FcX Fc Receptor Blocking Solution	BioLegend	422302	Fc Receptor Blocking Solution for blocking of Fc Receptors from biologically relevant samples
Innovatis CASY cell counter and analyzer TT	Biovendis Products GmbH		For the counting of cells and the determination of cell size and volume based on the exclusion of electric current.
KCl, Potassium chloride	Merck, Sigma-Aldrich	P5405	Powder, BioReagent, suitable for cell culture
L-Glutamine 200 mM (100x)	ThermoFisher Scientific, Gibco	25030-024
MgCl2, Magessium chloride	Merck, Sigma-Aldrich	M2393	BioReagent, suitable for cell culture, suitable for insect cell culture
Microtube Insert for 24 x 1.5/2.0 mL tubes	Keison Products	P-2-24	Microtube insert for Grant Bio MPS-1 Multi Plate Shaker
Mini Incubator	Labnet International	I5110A-230V	For the incubation (co-culturing) of BSLB and cells in the absence of CO2
Minimum Essential Medium Non-Essential Amino Acids	ThermoFisher Scientific, Gibco	11140-035
Mouse IgG polyclonal antibody control	Merck, Sigma-Aldrich	PP54	Used as positive control for the measurement of antibodies bound to mouse IgG capture bead standards
Mouse IgG1, k Isotype, clone MOPC-21	BioLegend	400129, 400112, 400130, 400144, 400128 and 400170	Alexa Fluor 488, PE, Alexa Fluor 647, Alexa Fluor 700, APC/Cyanine7 and Brilliant Violet 785  conjugates, respectively.
Mouse IgG1, k Isotype, clone X40	Becton Dickinson & Company (BD), Horizon	562438	Brilliant Violet 421 conjugate.
Mouse IgG1, κ Isotype control, clone P3.6.2.8.1	eBioscience	14-4714-82	Labeled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
Mouse IgG2a, k Isotype, clone MOPC-173	BioLegend	400240	Alexa Fluor 647 conjugate
Mouse IgG2b, k Isotype, clone MPC-11	BioLegend	400330 and 400355	Alexa Fluor 647 and Brilliant Violet 785 conjugates, respectively
Multiwell 6 well Tissue culture treated with vacuum gas plasma	Falcon	353046	For culturing and expanding purified CD4+ and CD8+ T cells.
Na2HPO4, Disodium Phosphate	Merck, Sigma-Aldrich	S7907
NaCl, Sodium chloride	Merck, Sigma-Aldrich	S5886	BioReagent, suitable for cell culture, suitable for insect cell culture, suitable for plant cell culture, ≥99%
NiSO4, Nickel(II) sulfate	Merck, Sigma-Aldrich	656895	For saturating NTA sites; added during the blocking process
Penicillin Streptomycin [+]10,000 units Penicillin; [+] 10,000 µg/mL Streptomycin	ThermoFisher Scientific, Gibco	15140-122
Phosphate Buffered Saline pH 7.4, sterile	ThermoFisher Scientific, Gibco	10010	No Ca2+ or Mg2+ added
Polyethersulfone (PES) Filter unit	Thermo Scientific Nalgene	UY-06730-43	Hydrophilic PES membrane with low protein binding facilitates the filtering of solutions with high protein content
PURESHIELD argon ISO 14175-I1-Ar	BOC Ltd.	11-Y	For the protection of lipid stocks stored at +4 ºC.
Purified Streptavidin	BioLegend	280302
Quantum Alexa Fluor 488 MESF beads	Bangs Laboratories Inc.	488	Benchmark beads for the interpolation of Alexa Fluor 488 molecules bound to cells and/or BSLB
Quantum Alexa Fluor 647 MESF beads	Bangs Laboratories Inc.	647	Benchmark beads for the interpolation of Alexa Fluor 647 molecules bound to cells and/or BSLB
Rat anti-mouse IgG Kappa Light Chain, clone OX-20	ThermoFisher Scientific, invitrogen	SA1-25258	Labeled in house with Alexa Fluor 647 NHS Ester (Succinimidyl Ester)
Recombinant human IL-2	Peprotech	200-02-1MG
RMPI Medium 1640 (1x); [-] L-Glutamine	ThermoFisher Scientific, Gibco	31870-025
Rosette Human B Cell Enrichment Cocktail	STEMCELL Technologies	15064	Isolation of B cells for measuring densities of proteins in purified cell populations
Rosette Human CD4+ T Cell Enrichment Cocktail	STEMCELL Technologies	15022C.1
Rosette Human CD4+CD127low T Cell Enrichment Cocktail	STEMCELL Technologies	15361	Pre-enrichment of CD4+ CD127Low T cells for the downstream isolation of Tregs by FACS.
Rosette Human CD8+ T Cell Enrichment Cocktail	STEMCELL Technologies	15063
RPMI Medium 1640 (1x); [-] Phenol Red	ThermoFisher Scientific, Gibco	11835-063	For the incubation (co-culturing) of BSLB and cells in the absence of CO2. Phenol red-free media reduces the autofluorescence of cells in flow cytometry and microscopy based measurements.
Sodium Pyruvate (100 mM)	ThermoFisher Scientific, Gibco	11360-070
Sprout mini centrifuge	FisherScientific, Heathrow Scientific LLC	120301	Benchtop microcentrifuge used to wash silica beads and BSLB in 1.5 mL Eppendorf tubes.
Sterile cappeed 5 mL polystyrene round-bottom tubes	Falcon	352058
UltraComp eBeads Compensation Beads	ThermoFisher Scientific, invitrogen	01-2222-42
Zeba Spin Desalting Columns 7K MWCO	Thermo Fisher Scientific, Invitrogen™	89882