BIOMAT Database Logo BIOMAT Database Logo

Pronase treatment improves flow cytometry crossmatching results. 2017

M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Department of Histocompatibility, Amiens University Medical Center, Amiens, France.

Flow cytometry crossmatching (FC-XM) is the most sensitive cell-based method for detecting donor-specific antibodies in clinical organ transplantation. Unfortunately, background FC-XM reactivity is elevated in assays with B lymphocytes-partly because of nonspecific immunoglobulin binding by Fc receptors and B-cell surface immunoglobulins. To reduce the background reactivity in a B-cell FC-XM assay, we treated lymphocytes with pronase (1 mg/mL for 30 minutes). This treatment drastically reduced the presence of kappa light chains and Fc receptors (CD32b), while the concomitant decrease in CD19, CD20 and major histocompatibility complex (MHC) I and II expression on B-cells was acceptable. Higher pronase concentrations (>2 mg/mL) started to significantly affect CD19, CD20, MHC-I and -II expression on B-cells. In subsequent prospective experiments (on 42 donor cells tested with 102 sera), we found that pronase treatment was associated with a relative increase of the sensitivity and specificity in our B-cell FC-XM assay.

UI MeSH Term Description Entries
D008297 Male Males
D011402 Pronase A proteolytic enzyme obtained from Streptomyces griseus. Pronase E,Pronase P,Protease XIV,XIV, Protease
D005260 Female Females
D005434 Flow Cytometry Technique using an instrument system for making, processing, and displaying one or more measurements on individual cells obtained from a cell suspension. Cells are usually stained with one or more fluorescent dyes specific to cell components of interest, e.g., DNA, and fluorescence of each cell is measured as it rapidly transverses the excitation beam (laser or mercury arc lamp). Fluorescence provides a quantitative measure of various biochemical and biophysical properties of the cell, as well as a basis for cell sorting. Other measurable optical parameters include light absorption and light scattering, the latter being applicable to the measurement of cell size, shape, density, granularity, and stain uptake. Cytofluorometry, Flow,Cytometry, Flow,Flow Microfluorimetry,Fluorescence-Activated Cell Sorting,Microfluorometry, Flow,Cell Sorting, Fluorescence-Activated,Cell Sortings, Fluorescence-Activated,Cytofluorometries, Flow,Cytometries, Flow,Flow Cytofluorometries,Flow Cytofluorometry,Flow Cytometries,Flow Microfluorometries,Flow Microfluorometry,Fluorescence Activated Cell Sorting,Fluorescence-Activated Cell Sortings,Microfluorimetry, Flow,Microfluorometries, Flow,Sorting, Fluorescence-Activated Cell,Sortings, Fluorescence-Activated Cell
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D000949 Histocompatibility Antigens Class II Large, transmembrane, non-covalently linked glycoproteins (alpha and beta). Both chains can be polymorphic although there is more structural variation in the beta chains. The class II antigens in humans are called HLA-D ANTIGENS and are coded by a gene on chromosome 6. In mice, two genes named IA and IE on chromosome 17 code for the H-2 antigens. The antigens are found on B-lymphocytes, macrophages, epidermal cells, and sperm and are thought to mediate the competence of and cellular cooperation in the immune response. The term IA antigens used to refer only to the proteins encoded by the IA genes in the mouse, but is now used as a generic term for any class II histocompatibility antigen. Antigens, Immune Response,Class II Antigens,Class II Histocompatibility Antigen,Class II Major Histocompatibility Antigen,Ia Antigens,Ia-Like Antigen,Ia-Like Antigens,Immune Response Antigens,Immune-Associated Antigens,Immune-Response-Associated Antigens,MHC Class II Molecule,MHC II Peptide,Class II Antigen,Class II Histocompatibility Antigens,Class II MHC Proteins,Class II Major Histocompatibility Antigens,Class II Major Histocompatibility Molecules,I-A Antigen,I-A-Antigen,IA Antigen,MHC Class II Molecules,MHC II Peptides,MHC-II Molecules,Antigen, Class II,Antigen, I-A,Antigen, IA,Antigen, Ia-Like,Antigens, Class II,Antigens, Ia,Antigens, Ia-Like,Antigens, Immune-Associated,Antigens, Immune-Response-Associated,I A Antigen,II Peptide, MHC,Ia Like Antigen,Ia Like Antigens,Immune Associated Antigens,Immune Response Associated Antigens,MHC II Molecules,Molecules, MHC-II,Peptide, MHC II,Peptides, MHC II
D001402 B-Lymphocytes Lymphoid cells concerned with humoral immunity. They are short-lived cells resembling bursa-derived lymphocytes of birds in their production of immunoglobulin upon appropriate stimulation. B-Cells, Lymphocyte,B-Lymphocyte,Bursa-Dependent Lymphocytes,B Cells, Lymphocyte,B Lymphocyte,B Lymphocytes,B-Cell, Lymphocyte,Bursa Dependent Lymphocytes,Bursa-Dependent Lymphocyte,Lymphocyte B-Cell,Lymphocyte B-Cells,Lymphocyte, Bursa-Dependent,Lymphocytes, Bursa-Dependent
D015395 Histocompatibility Antigens Class I Membrane glycoproteins consisting of an alpha subunit and a BETA 2-MICROGLOBULIN beta subunit. In humans, highly polymorphic genes on CHROMOSOME 6 encode the alpha subunits of class I antigens and play an important role in determining the serological specificity of the surface antigen. Class I antigens are found on most nucleated cells and are generally detected by their reactivity with alloantisera. These antigens are recognized during GRAFT REJECTION and restrict cell-mediated lysis of virus-infected cells. Class I Antigen,Class I Antigens,Class I Histocompatibility Antigen,Class I MHC Protein,Class I Major Histocompatibility Antigen,MHC Class I Molecule,MHC-I Peptide,Class I Histocompatibility Antigens,Class I Human Antigens,Class I MHC Proteins,Class I Major Histocompatibility Antigens,Class I Major Histocompatibility Molecules,Human Class I Antigens,MHC Class I Molecules,MHC-I Molecules,MHC-I Peptides,Antigen, Class I,Antigens, Class I,I Antigen, Class,MHC I Molecules,MHC I Peptide,MHC I Peptides,Molecules, MHC-I,Peptide, MHC-I,Peptides, MHC-I
D015703 Antigens, CD Differentiation antigens residing on mammalian leukocytes. CD stands for cluster of differentiation, which refers to groups of monoclonal antibodies that show similar reactivity with certain subpopulations of antigens of a particular lineage or differentiation stage. The subpopulations of antigens are also known by the same CD designation. CD Antigen,Cluster of Differentiation Antigen,Cluster of Differentiation Marker,Differentiation Antigens, Leukocyte, Human,Leukocyte Differentiation Antigens, Human,Cluster of Differentiation Antigens,Cluster of Differentiation Markers,Antigen Cluster, Differentiation,Antigen, CD,CD Antigens,Differentiation Antigen Cluster,Differentiation Marker Cluster,Marker Cluster, Differentiation

Related Publications

M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Pronase independent flow cytometry crossmatching of rituximab treated patients.
February 2018, Human immunology,
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Lymphocyte crossmatching by flow cytometry.
January 2013, Methods in molecular biology (Clifton, N.J.),
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Flow cytometry crossmatching: an update.
January 1989, Clinical transplants,
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Flow cytometry crossmatching for kidney transplantation.
February 1993, Transplantation proceedings,
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Crossmatching on platelets by flow cytometry.
January 1988, Clinical transplants,
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Flow cytometry crossmatching for kidney transplantation.
January 1988, Clinical transplants,
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Pronase treatment facilitates alloantibody flow cytometric and cytotoxic crossmatching in the presence of rituximab.
August 2004, Human immunology,
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Improved flow cytometry crossmatching in kidney transplantation.
December 2018, HLA,
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Flow cytometry crossmatching for solid organ transplantation.
January 1994, Methods in cell biology,
M-J Apithy, and J Desoutter, and A Gicquel, and E Guiheneuf, and P-F Westeel, and A Lesage, and V Piot, and G Choukroun, and N Guillaume
Flow cytometry crossmatching in donor/recipient selection.
October 1991, Transplantation proceedings,
Copied contents to your clipboard!