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Abstract
Introduction
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Measuring Erythrocyte Complement Receptor 1 Using Flow Cytometry

Published: May 19, 2020
doi:
10.3791/60810
, , , , ,
1Oncogeriatric Coordination Unit,Reims University Hospitals, Maison Blanche Hospital, 2Faculty of Medicine,University of Reims Champagne-Ardenne, 3URCACyt, Flow cytometry technical platform,University of Reims Champagne-Ardenne, 4Department of Immunology,Reims University Hospitals, Robert Debre Hospital, 5Department of Internal Medicine and Geriatrics,Reims University Hospitals, Maison Blanche Hospital, 6Faculty of Medicine,University of Reims Champagne-Ardenne

概要

The aim of this method is to determine the CR1 density in the erythrocytes of any subject by comparing with three subjects whose erythrocyte CR1 density is known. The method uses flow cytometry after immunostaining of the subjects' erythrocytes by an anti-CR1 monoclonal antibody coupled to an amplified system using phycoerythrin (PE).

Abstract

CR1 (CD35, Complement Receptor type 1 for C3b/C4b) is a high molecular weight membrane glycoprotein of about 200 kDa that controls complement activation, transports immune complexes, and participates in humoral and cellular immune responses. CR1 is present on the surface of many cell types, including erythrocytes, and exhibits polymorphisms in length, structure (Knops, or KN, blood group), and density. The average density of CR1 per erythrocyte (CR1/E) is 500 molecules per erythrocyte. This density varies from one individual to another (100–1,200 CR1/E) and from one erythrocyte to another in the same individual. We present here a robust flow cytometry method to measure the density of CR1/E, including in subjects expressing a low density, with the help of an amplifying immunostaining system. This method has enabled us to show the lowering of CR1 erythrocyte expression in diseases such as Alzheimer's disease (AD), systemic lupus erythematosus (SLE), AIDS, or malaria.

Introduction

CR1 (complement receptor type 1, CD35) is a 200 kDa transmembrane glycoprotein present on the surface of many cell types, such as erythrocytes1, B lymphocytes2, monocytic cells, some T cells, follicular dendritic cells3, fetal astrocytes4, and glomerular podocytes5. CR1 interfering with its ligands C3b, C4b, C3bi6,7,8,9, a subunit of the first complement component, C1q10 and MBL (mannan-binding lectin)11 inhibits the activation of complement and is involved in humoral and cellular immune response.

In primates, including humans, erythrocyte CR1 is involved in the transport of immune complexes to the liver and spleen, to purify the blood and prevent their accumulation in vulnerable tissues such as the skin or kidneys12,13,14. This phenomenon of immune adhesion between immune complexes and erythrocytes depends on the number of CR1 molecules15. In humans, the mean density of CR1/E is only 500 (i.e., 500 molecules of CR1 per erythrocyte). This density varies from one individual to another (100–1,200 CR1/E) and from one erythrocyte to another in the same individual. Some individuals of "null" phenotype express fewer than 20 CR1/E16.

The density of CR1/E is regulated by two co-dominant autosomal alleles linked to a point mutation in intron 27 of the gene coding for CR1*117,18. This mutation produces an additional restriction site for the HindIII enzyme. The restriction fragments obtained after digestion with HindIII in this case are 7.4 kb for the allele linked to a strong expression of CR1 (H: high allele) and 6.9 kb for the allele linked to low CR1 expression (L: low allele). This link is found in Caucasians and Asians but not in people of African descent19.

The level of expression of erythrocyte CR1 is also correlated with the presence of point nucleotide mutations in exon 13 encoding SCR 10 (I643T) and in exon 19 encoding SCR16 (Q981H). It is high in homozygous 643I/981Q and low in homozygous 643T/981H individuals20. Thus, "low" individuals express around 150 CR1/E, "medium" individuals express around 500 CR1/E, and "high" individuals express around 1,000 CR1/E.

In addition to this erythrocyte density polymorphism, CR1 is characterized by a length polymorphism corresponding to four allotypes of different sizes: CR1*1 (190 kDa), CR1*2 (220 kDa), CR1*3 (160 kDa), and CR1*4 (250 kDa)21 and an antigenic polymorphism corresponding to the blood group KN22.

We present our method based on flow cytometry to determine the density of CR1/E. Using three subjects whose CR1/E density is known, expressing a low density level (180 CR1/E), a medium density level (646 CR1/E), and a high density level (966 CR1/E), it is easy to measure the mean fluorescence intensity (MFI) of their erythrocytes or red blood cells (RBC), or RBC MFI, after anti-CR1 immunostaining using a flow cytometer. One can then plot a standard line representing the MFI as a function of CR1/E density. Measuring the MFI of subjects whose CR1/E density is not known and comparing it to this standard line, it is possible to determine the individuals' CR1/E density. This technique has been used for many years in the laboratory, and has enabled us to detect a reduction in the expression of erythrocyte CR1 in many pathologies such as systemic lupus erythematosus (SLE)23, Acquired immunodeficiency syndrome (AIDS)24, malaria25, and recently Alzheimer's disease (AD)26,27. The development of drugs targeting CR1 to couple with erythrocytes, as in the case of anti-thrombotic drugs28 requires the evaluation of CR1/E density, and the availability of a robust technique to quantify CR1.

The protocol presented runs in singlicate. It is adaptable to determine the density of CR1/E on many individuals using specific commercially available 96 well plates (see Table of Materials). To this end, it is easy to adapt our method to any 96 well plate. For each sample, a cell suspension of erythrocytes (0.5 x 106–1 x 106 erythrocytes) is distributed per well. For each well, first the primary anti-CR1 antibody is added, then streptavidin PE, the secondary anti-streptavidin antibody, and again streptavidin PE, using the same dilutions as those of our method, but by adapting volumes and respecting proportionality.

The blood samples from subjects of the range and from subjects to be quantified for CR1 should be drawn at the same time, stored in the refrigerator at 4 °C, and handled at 4 °C (on ice and/or in the refrigerator).

Protocol

The protocol for human blood collection and handling was reviewed and approved by the regional ethics committee (CPP Est II), and the protocol number is 2011-A00594-37. Because the following protocol describes the handling of human blood, institutional guidelines for disposing of biohazardous material should be followed. Laboratory safety equipment, such as lab coats and gloves, should be worn.

1. Erythrocyte washing

NOTE: The day before handling, prepare a PBS-BSA buffer with phosphate buffered saline (PBS) containing 0.15% of bovine serum albumin (BSA) and place it in the refrigerator at 4 °C. This buffer will be used as a washing buffer and as a dilution buffer.

  1. Pipette 20 mL of PBS-BSA into a 50 mL tube.
  2. Aspirate 250 µL of sodium ethylenediamine tetraacetic acid (EDTA) anticoagulated whole blood from blood storage tubes and add to the tube containing the 20 mL of PBS-BSA. Close the tube by screwing the cap. Mix gently by inverting the tube 2x.
  3. Centrifuge the tube for 10 min at 4 °C at 430 x g. Remove and discard the supernatant using a 10 mL pipette. Resuspend the pellet in the residual volume of supernatant by gentle and careful pipetting.
  4. Add 20 mL of cold PBS-BSA (4 °C) into the tube containing the pellet. Centrifuge the tube for 10 min at 4 °C at 430 x g. Remove and discard the supernatant using a 10 mL pipette.
  5. Add 20 mL of cold PBS-BSA (4 °C) into the tube containing the pellet. Centrifuge the tube for 10 min at 4 °C at 430 x g. Leave the tube in the centrifuge at 4 °C and go to section 2.

2. Erythrocyte dilution

  1. Pipette 3 mL of cold PBS-BSA into a 50 mL tube and store it at 4 °C on a rack in ice.
  2. Put the centrifuged tube containing the erythrocytes (step 1.4) on a rack placed in ice.
  3. Pipette 8 µL of pelleted erythrocytes using the pipette and add to the 50 mL tube containing the 3 mL of PBS-BSA to obtain the erythrocyte dilution. Mix the tube gently by hand to obtain a homogeneous cell suspension of erythrocytes.

3. Erythrocyte immunostaining

  1. Pipette 100 µL of erythrocyte dilution (obtained in section 4) and add to 1.4 mL tubes.
  2. Centrifuge the tubes for 5 min at 4 °C at 430 x g. During centrifugation, prepare a dilution of biotinylated anti-CR1 J3D3 antibody at a concentration of 0.05 μg/μL in PBS-BSA buffer.
  3. Once the centrifugation is done, remove and discard the supernatant.
  4. Add 20 µL of biotinylated anti-CR1 J3D3 directly to the pellet. To prepare the negative control, add 20 µL of PBS-BSA buffer instead. Mix the tubes gently and incubate for 45 min at 4 °C.
  5. After 45 min of incubation, add 750 µL of PBS-BSA to the tubes. Centrifuge the tubes for 5 min at 4 °C at 430 x g. Remove and discard the supernatant. Repeat.
  6. In the meantime, prepare a 1:10 dilution of streptavidin-phycoerythrin diluted in PBS-BSA buffer. Pipette 20 µL of the 1:10 dilution of streptavidin-phycoerythrin and add to the tubes. Mix the tubes gently and incubate for 45 min at 4 °C.
  7. Add 750 µL of PBS-BSA buffer into the tubes. Mix well and centrifuge for 5 min at 4 °C at 430 x g. Remove and discard the supernatant. Repeat.
  8. During centrifugation, prepare a 1:100 dilution of biotinylated anti-streptavidin antibody diluted in PBS-BSA buffer.
  9. Once the centrifugation is done, remove and discard the supernatant.
  10. Pipette 20 µL of the 1:100 dilution of biotinylated anti-streptavidin into the tubes. Mix the tubes gently. Incubate the tubes for 45 min at 4 °C.
  11. After 45 min of incubation, pipette 750 µL of PBS-BSA buffer and add into the tubes. Centrifuge the tubes for 5 min at 4 °C at 430 x g. Remove and discard the supernatant. Repeat.
  12. Pipette 20 µL of the 1:10 dilution of streptavidin-phycoerythrin and add into the tubes. Mix the tubes gently. Incubate the tubes for 45 min at 4 °C.
  13. Pipette 750 µL of PBS-BSA buffer and add into the tubes. Mix well and centrifuge the tubes for 5 min at 4 °C at 430 x g. Remove and discard the supernatant. Repeat this step 2x.

4. Immunostained erythrocyte fixation

  1. During the last centrifugation, prepare the fixation buffer, a 1:100 dilution of 37% formaldehyde using the washing buffer PBS-BSA.
  2. Pipette 450 μL of fixation buffer and add into immunostained erythrocyte tubes (from step 3.13) while vortexing for 5 s.
  3. Pipette all fixed cells into 5 mL round bottom tubes and store in the refrigerator.
    NOTE: The protocol can be paused here for up to 48 h.

5. Flow cytometry analysis of stained erythrocytes

NOTE: It is advisable to refer to the operator's manual for the cytometer (see Table of Materials) to know how to perform the cytometric readings. The suggested parameters below apply to the instrument used and must be optimized for each cytometer.

  1. Turn on the flow cytometer, then turn on the computer. Let the optical system temperature stabilize by leaving it on for 30 min. Check the cytometer window in the software to ensure that the cytometer is connected to the workstation (the message Cytometer Connected is displayed).
  2. Check that the buffer container is full and that the waste container is empty. Remove air bubbles in the buffer filter and the buffer line using the purge system. Prime the fluidics system by pressing the Prime button on the console of the cytometer. Wait until the indicator light changes from red to green.
  3. To clean the fluidics, install a tube containing 3 mL of a cleaning solution on the sample injection port and allow the cleaning solution to run for 5 min with a high sample flow rate. Repeat this with the rinse solution with distilled water. Leave the tube containing water on the sample injection port.
  4. To prepare the calibrating beads, pipette 400 µL of PBS into the bottom of a round bottom tube. Mix the bead stocks strongly by vortexing for 30 s. Add a drop to the round bottom tube containing PBS. Mix carefully by vortexing for 30 s.
  5. Run the performance check. Open the cytometer Setup and Tracking module in the software (Figure 1A). Verify that the cytometer configuration is correct for the experiment using PE immunostaining. Verify that the calibrating bead batch is correct with the configuration.
  6. Install the bead tube on the sample injection port and let it run with a low sample flow rate. Run the performance check, which takes approximately 5 min to complete). Once the performance check is complete, verify that the cytometer performance is satisfactory (Figure 1B). Close the cytometer Setup and Tracking module in the software.
  7. To set up an experiment and create application settings, click the New Experiment button on the browser toolbar and open the new experiment. Specify the parameters by selecting appropriate cytometer settings: Forward Scatter (FSC), Side Scatter (SSC), and PE from the drop-down menu of the experiment (Figure 1C). Select Linear Mode for FSC parameter and Logarithm Mode for SSC and PE parameters.
  8. In the open experiment, select Cytometer Settings (Figure 1D), then select Application Settings, and create a global worksheet (Figure 1E). Use the gray boxes and crosshairs to guide the optimization.
  9. Load the unstained control tube onto the cytometer and run Acquisition. Ensure that the population of interest (i.e., RBCs) is on scale by optimizing the FSC and SSC voltages. Optimize the FSC threshold value to eliminate debris without interfering with the population of interest.
  10. Draw a gate around the RBCs on the FSC vs. SSC plot. Display the RBC population in the dot plot of PE fluorescence. If needed, increase the fluorescence of the photomultiplier tube (PMT) voltages to place the negative population within the gray boxes. Unload the unstained control tube from the cytometer.
  11. Verify that the positive populations are on scale. Load the stained control tube onto the cytometer and run Acquisition. Lower the PMT voltage for the positive population if it is off scale until the positive population can be seen entirely on scale. Then unload the stained sample.
  12. To record and analyze samples, on a new global worksheet, create the following plots for previewing the data: 1) FSC vs. SSC, and 2) PE fluorescence histogram. Load the first sample onto the cytometer and run Acquisition.
  13. Draw an RBC gate around the erythrocytes on the FSC vs. SSC plot. Display the RBC population in the PE fluorescence histogram. In the 統計 view, select the mean for PE fluorescence parameters on GR populations (Figure 1F).
  14. In the Acquisition dashboard, select all events in the stopping gate and 10,000 events to record (Figure 1G). Click Record Data. When the event recording has completed, remove the first tube from the cytometer. The global worksheet plots should look like those in Figure 2.
  15. Load the following samples and record them.

6. Determination of the density of erythrocyte CR1

  1. Take the values of the mean fluorescence intensities of the samples corresponding to the "low" subject (Figure 3, Table I, RBC MFI), "medium" subject (Figure 4, Table D, RBC MFI), "high" subject (Figure 4, Table I, RBC MFI), and to the negative control sample (Figure 3, Table I, RBC MFI).
  2. On a graph representing the mean fluorescence intensity as a function of the density of CR1, place the four points corresponding to the negative control, "low" subject, "medium" subject, and "high" subject (blue points, Figure 6).
  3. Draw the regression line to get the calibration line and its equation.
  4. Take the values of the mean fluorescence intensity of the samples corresponding to the subjects whose density is to be determined. (Figure 5, Tables D and I, RBC MFI).
  5. Obtain the equation by replacing "Y" using the values of the mean fluorescence intensities, and calculate the density of CR1/E (Figure 6).
  6. Check on the graph that the mean fluorescence intensity values and the determined CR1/E density correspond to a point on the calibration line (Figure 6).

Representative Results

The erythrocytes of three subjects whose density of CR1 is known ("low" subject [180 CR1/E], "medium" subject [646 CR1/E], and "high" subject [966 CR1/E]), and of two subjects whose CR1 density needed to be determined were immunostained by an anti-CR1 antibody coupled to an amplification system using the phycoerythrin fluorochrome. At the beginning, the CR1 density of the subjects from the low-high range was determined by the Scatchard method29 using radiolabeled antibodies. The standards (low, medium, and high) determined were used for a calibration curve and made it possible to quantify new standards or substandards by our method of cytometry30. After passage of immunostained erythrocytes in the flow cytometer, the intensity of the labeling was observed and measured as the mean fluorescence intensity for each subject (RBC MFI) (Figure 3F,I; Figure 4B,D,F,I; Figure 5B,D,F,I). A curve was plotted using the values of the subjects with the known density of erythrocyte CR1 ("low" to "high") by reporting them as a function of the mean fluorescence intensity. Comparison of the regression line resulting from this curve to the values of the mean fluorescence intensity of the other subjects determined their CR1/E density (Figure 6). Figure 7 shows the overall workflow.

Figure 1
Figure 1: Cytometer console and windows appearing during flow cytometry protocol. (A) Window appearing after the application of step 5.5 of the protocol. (B) Window appearing after the application of step 5.6 of the protocol. (C) Window appearing after the application of step 5.7 of the protocol. (D) Window appearing after the application of step 5.8 of the protocol. (E) Window appearing after the application of step 5.8 of the protocol. (F) Window appearing after the application of step 5.13 of the protocol. (G) Window appearing after the application of step 5.14 of the protocol. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Appearance of the global worksheet analysis objects. Appearance of the global worksheet analysis objects after the application of step 5.14 of the protocol. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Results of flow cytometry analysis of anti-CR1 immunostaining of erythrocytes corresponding to negative control and to the subject from the range ("low" subject) who expressed LOW CR1 density (180 CR1/E). For each subject: (A,E) a dot blot showing the appearance of events acquired according to the size and granulometry parameters, (G) the gate selecting the erythrocyte population among the events, (B,F) a histogram representing the intensity of the labeling, (C,H) an associated statistical table presenting the number of events corresponding to the erythrocytes and their percentage, (D,I) an associated table giving the mean fluorescence intensity (RBC MFI). Please click here to view a larger version of this figure.

Figure 4
Figure 4: Results of flow cytometry analysis of anti-CR1 immunostaining of erythrocytes corresponding to the subjects from the range: "medium" subject who expressed MEDIUM CR1 density (646 CR1/E) and "high" subject who expressed HIGH CR1 density (966 CR1/E). For each subject: (A, E) a dot blot showing the appearance of events acquired according to the size and granulometry parameters, (G) the gate selecting the erythrocyte population among the events, (B, F) a histogram representing the intensity of the labeling, (C, H) an associated statistical table presenting the number of events corresponding to the erythrocytes and their percentage, (D, I) an associated table giving the mean fluorescence intensity (RBC MFI). Please click here to view a larger version of this figure.

Figure 5
Figure 5: Results of flow cytometry analysis of anti-CR1 immunostaining of erythrocytes corresponding to the subjects whose CR1 density was to be determined. For each subject: (A, E) a dot blot showing the appearance of events acquired according to the size and granulometry parameters, (G) the gate selecting the erythrocyte population among the events, (B, F) a histogram representing the intensity of the labeling, (C, H) an associated statistical table presenting the number of events corresponding to the erythrocytes and their percentage, (D, I) an associated table giving the mean fluorescence intensity (RBC MFI). Please click here to view a larger version of this figure.

Figure 6
Figure 6: Calibration curve and regression line enabling determination of CR1 density. (A), (B) Calibration curve and regression line drawn according to the known CR1 density of the range subjects (negative control: 0 CR1, "low" subject [180 CR1/E], "medium" subject [646 CR1/E], and "high" subject [966 CR1/E]) and their respective values of mean fluorescence intensity obtained by flow cytometry. (C), (D) From the equation of this regression line, we calculated the density of erythrocyte CR1 for subjects whose mean fluorescence intensity was quantified by flow cytometry: orange arrows, Subject 1 (mean fluorescence intensity = 1,334; CR1/E density = 459) and Subject 2 (mean fluorescence intensity = 2820; CR1/E density = 1,000). Please click here to view a larger version of this figure.

Figure 7
Figure 7: Flowchart of the protocol to determine the erythrocyte CR1 density from human blood samples. Collect a human blood sample. Wash the human blood sample by centrifugation to obtain erythrocytes. Stain the erythrocytes using an anti-CR1 antibody. Use flow cytometry to determine the erythrocyte CR1 density according to a calibration curve. Please click here to view a larger version of this figure.

Discussion

Several techniques are available to determine the density of erythrocyte CR1 (CR1/E). The first techniques used were the agglutination of red blood cells by anti-CR1 antibodies31 and the formation of rosettes in the presence of erythrocytes coated with C3b32. These rudimentary techniques were rapidly replaced by immunostaining methods using radiolabeled anti-CR1 antibodies1,33. It is also possible to measure the concentration of CR1 in membrane extracts by enzyme-linked immunosorbent assay (ELISA)34. Although accurate, these techniques only provide an average value of the CR1/E density. The distribution of CR1/E density over the entire erythrocyte population is only available by flow cytometric analysis after immunostaining. This technique is difficult due to the low density of CR1/E. Nevertheless, an amplification method now makes it possible to easily measure the density of CR1/E30.

Here, we present a method of quantifying CR1/E by flow cytometry based on amplification of the fluorescence signal of immunostained cells. The amplification system involves four successive layers of staining using the biotinylated anti-CR1 monoclonal antibody J3D3; phycoerythrin-streptavidin; a biotinylated goat anti-streptavidin antibody; and again phycoerythrin-streptavidin. J3D3 recognizes three antigenic sites on CR135, although no more than one at the same time. The biotinylated goat anti-streptavidin antibody is a polyclonal antibody that recognizes multiple epitopes on streptavidin and provides a better bridge between the two streptavidin layers than biotin-streptavidin alone. This process also benefits from the high fluorescence yield of phycoerythrin36 and the low level of nonspecific binding of streptavidin37. With such a strong amplified signal, the low settings of the cytometer photomultiplier tubes enable perfect linearity. This method, which is characterized by excellent sensitivity and reproducibility, enables the detection of fewer than 100 CR1/cell.

However, this method requires samples from three subjects whose density of erythrocyte CR1 is known: one subject expressing a low level of erythrocyte CR1 (180 CR1/E), one subject expressing a medium level of erythrocyte CR1 (646 CR1/E) and one subject expressing a high level of erythrocyte CR1 (966 CR1/E). It is possible to take the first measurements of the erythrocyte CR1 density of several individuals, initially using the erythrocytes from the three subjects used in our study, which we can provide. The blood samples from subjects of the range and subjects to be quantified for CR1 should be drawn at the same time, stored in the refrigerator at 4 °C, and handled at 4 °C38. The blood drawn in EDTA tubes is easily routable and can be stored for 5 days at 4 °C, allowing time for quantification of erythrocyte CR1. After this, the density of erythrocyte CR1 begins to decrease, and there is a collapse of the standard CR1 curve, especially at the point corresponding to the subject expressing a high level of erythrocyte CR1. Because the resulting regression line is distorted, the measure of CR1 density is no longer accurate. It should be noted that in vitro storage, handling conditions, and the multilayered staining lead to clustering of CR1 and a slight overestimation of the number of CR1 molecules. Nevertheless, the use of an anti-CR1 antibody targeting three epitopes such as J3D3 with the amplification system enables clustering to be fully performed, which enables correct measurement of CR1 density39.

In fact, the density of CR1/E decreases during the life of the erythrocyte40. This would explain the heterogeneity of the density of CR1/E in the same individual. According to some authors, the intensity of catabolism of CR1 is not correlated with the initial density of CR1/E41, whereas for other authors, the higher the initial density, the greater the intensity of catabolism42. The half-life of CR1 on the surface of erythrocytes is 11–32 days42.

The method presented here has several advantages. The first is to be able to select, thanks to flow cytometry, the cell subpopulations to be studied within the same blood sample. By selecting the erythrocyte population using the gate function, the measurement of erythrocyte density is guaranteed exclusively. A bias in the measurement of erythrocyte CR1 caused by the presence of other cellular subpopulations such as white blood cells is avoided. The second advantage of this method is that it is adaptable to the quantification of other cellular receptors whose density is low by simply replacing the primary anti-CR1 antibody with an antibody specifically directed against an epitope of the receptor to be studied. It is also adaptable to using 96 well plates instead of tube racks, which requires lower blood and reagent volumes25,38. The third advantage of this method is that it is flexible. In studies concerning cells with a very high density of CR1, for example, human lymphocytes (10,000 CR1/cell), or nonhuman primate erythrocytes whose CR1 density is 10–100x greater than that of humans (10,000–100,000 CR1/cell)43,44, it is possible to decrease the number of amplification system layers, using only biotinylated anti-CR1 monoclonal antibody, phycoerythrin-streptavidin or biotinylated anti-CR1 monoclonal antibody, biotinylated anti-mouse antibody, and phycoerythrin-streptavidin, thus adapting the fluorescence level to the higher density of CR1. The fourth advantage of this method is that it can be used for fixed or frozen erythrocytes, enabling blood samples to be collected in areas lacking the facilities for flow cytometry and stored for later accurate quantification of CR138.

More generally, with the new brighter fluorochromes, it no longer seems mandatory to use the system of indirect amplification. Besides, there are other methods using flow cytometry that make it possible to evaluate the density of the cellular receptors and to quantify it in units of measure (i.e. ABC, or antibody binding capacity). The ABC per cell can also be determined using saturating concentrations of antibody and calibrated beads. Several commercial systems are available. Some kits are precalibrated standard beads containing known levels of fluorochrome molecules such as PE bound per bead. The beads acquired on a flow cytometer on the same day at the same instrument settings as the individual patient specimens make it possible to draw a standard curve comparing the geometric mean of fluorescence to known PE content of the beads. The regression analysis, slope, intercept, and correlation coefficient are determined, and the ABC values are calculated from the measured geometric mean fluorescence of cells using the standard curve45,46.

A further type of bead test is based on binding of an antibody conjugated to beads with specific antibody binding capacity levels via the crystallizable portion of the fragment (Fc). Beads are labeled with the same antibody used to label the cells whose antigen density is to be measured. Thus, in a single experiment, any conjugated antibody can be used, as long as the same batch with the same fluorophore/protein ratio (F/P ratio) is used to stain both beads and cells47. Some kits are better for the quantitative determination of cell surface antigens by flow cytometry using indirect immunofluorescence assays48,49.

In conclusion, our method has the advantage of providing very sensitive detection and being easy to implement on ordinary flow cytometry material.

開示

The authors have nothing to disclose.

Acknowledgements

We thank all the members of the URCACyt, flow cytometry technical platform, the staff of the Department of Immunology, and the staff of the Department of Internal Medicine and Geriatrics, who contributed to optimizing and validating the protocol. This work was funded by Reims University Hospitals (grant number AOL11UF9156).

Materials

1000E Barrier Tip Thermo Fischer Scientific , F-67403 Illkirch, France 2079E sample pipetting
1-100 µL Bevelled, filter tip Starlab GmbH, D-22926 Ahrenburg, Germany S1120-1840 sample pipetting
Biotinylated anti-CR1 monoclonal antibody (J3D3) Home production of non-commercial monoclonal antibody, courtesy of Dr J. Cook immunostaining
Blouse protection
Bovin serum albumin (7,5%) Thermo Fischer Scientific , F-67403 Illkirch, France 15260037 cytometry
Centrifuge Thermo Fischer Scientific , F-67403 Illkirch, France 11176917 centrifugation
Clean Solution BD, F-38801 Le Pont de Claix, France 340345 cytometry
Comorack-96 Dominique DUTSCHER SAS, F-67172 Brumath 944060P rack
Cytometer Setup & Tracking Beads Kit BD, F-38801 Le Pont de Claix, France 655051 cytometry
Formaldehyde solution 36.5 % Sigma Aldrich, F-38070 Saint Quentin Fallavier, France F8775-25ML Fixation
10 µL Graduated, filter tip Starlab GmbH, D-22926 Ahrenburg, Germany S1121-3810 sample pipetting
LSRFORTESSA Flow Cytometer BD, F-38801 Le Pont de Claix, France 647788 cytometry
Microman Capillary Pistons Dominique DUTSCHER SAS, F-67172 Brumath 067494 sample pipetting
Micronic 1.40 mL round bottom tubes Dominique DUTSCHER SAS, F-67172 Brumath MP32051 mix
Micropipette Microman – type M25 – Dominique DUTSCHER SAS, F-67172 Brumath 066379 sample pipetting
Phosphate buffered Saline (PBS) Thermo Fischer Scientific , F-67403 Illkirch, France 10010031 cytometry
Pipette PS 325 mm, 10 mL Dominique DUTSCHER SAS, F-67172 Brumath 391952 sample pipetting
powder-free Nitrile Exam gloves Medline Industries, Inc, Mundelein, IL 60060, USA 486802 sample protection
Reference 2 pipette, 0,5-10 µL Eppendorf France SAS, F-78360 Montesson, France 4920000024 sample pipetting
Reference 2 pipette, 20-100 µL Eppendorf France SAS, F-78360 Montesson, France 4920000059 sample pipetting
Reference 2 pipette, 100-1000 µL Eppendorf France SAS, F-78360 Montesson, France 4920000083 sample pipetting
Rinse Solution BD, F-38801 Le Pont de Claix, France 340346 cytometry
Round bottom tube Sarstedt, F-70150 Marnay, France 55.1579 cytometry
Safe-Lock Tubes, 1.5 mL Eppendorf France SAS, F-78360 Montesson, France 0030120086 mix
streptavidin R-PE Tebu Bio, F-78612 Le Perray-en-Yvelines, France AS-60669 immunostaining
Tapered Centrifuge Tubes 50 mL Thermo Fischer Scientific , F-67403 Illkirch, France 10203001 mix
Vector anti streptavidin biotin Eurobio Ingen, F-91953 Les Ulis, France BA-0500 immunostaining
Vortex-Genie 2 Scientific Industries, Inc, Bohemia, NY 111716, USA SI-0236 mix
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参考文献

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ErythrocyteComplement Receptor 1Flow CytometryCell Receptor DensityImmunostainingBiotinylated AntibodyStreptavidin Phycoerythrin

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Kisserli, A., Audonnet, S., Duret, V., Tabary, T., Cohen, J. H. M., Mahmoudi, R. Measuring Erythrocyte Complement Receptor 1 Using Flow Cytometry. J. Vis. Exp. (159), e60810, doi:10.3791/60810 (2020).
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