Binding of prostaglandins to human PPARgamma: tool assessment and new natural ligands.

The peroxisome proliferator-activated receptors (PPAR) form a family of nuclear receptors with a wide variety of biological roles from adipogenesis to carcinogenesis. More ligands (agonist and antagonist) are needed to explore the multiple functions of PPAR, particularly PPARgamma. In order to complete such ligand screening, a binding test should be assessed versus the classical transactivation reporter gene assay. In the present work, the full-length human PPARgamma protein as well as its ligand binding domain portion were expressed in Escherichia coli. Bacterial membrane preparations expressing those constructs were characterized using a classical binding competition assay [3H]rosiglitazone as the radioligand. When the receptor preparations were soluble, binding had to be measured with a new alternative method. The systems were assessed using a series of reference PPAR (alpha, beta and gamma) ligands. The full-length human PPARgamma fused to glutathione-S-transferase, expressed in E. coli and tested as a bacterial membrane-bound protein led to the most accurate results when compared to the literature. Furthermore, in an attempt to complete the panel of natural PPARgamma ligands, 29 commercially available prostaglandins were screened in the binding assay. Prostaglandins H(1) and H(2) were found to be modest ligands, however as potent as 15Delta(12-14 )prostaglandin J(2). These results were confirmed in the classical transactivation assay. The fact that these three prostaglandins were equally potent, suggests new pathways of PPARgamma-linked gene activation.

Fine characterization of a series of new monoclonal antibodies directed against glycophorin A.

OBJECTIVES: Glycophorins A (GPA) and B (GPB) are the major sialoglycoproteins of the human erythrocyte (RBC) membrane. To prepare tools for the analysis of GPA and GPB, we produced a series of new monoclonal antibodies (mAbs) that identified epitopes of GPA. METHODS: Seven murine monoclonal antibodies directed to glycophorin A (GPA) were fully characterized by agglutination of untreated and enzyme-treated human erythrocytes, inhibition of agglutination using chemically modified glycophorins and peptides from GPA, immunoblotting, and binding to synthetic peptides on plastic pins. RESULTS: The antibodies identify epitopes located on four different portions of GPA. (1) NaM13-6D2 binds to the N-terminal portion of GPA and GPB carrying the N blood group antigen; (2) NaM26-3F4 recognizes the homologous portion of GPA and GPB corresponding to their amino acids 6-26; (3) NaM10-2H12, NaM16-IB10 and NaM10-6G4 are specific for the amino acid sequence 38-45 of GPA; and (4) NaM37-5F4 and NaM13-4E4 bind to the amino acid residues 119-124 located on the intracellular ponion of GPA. CONCLUSION: These antibodies represent precise tools to investigate GPA and related molecules in different cells and tissues.

Flow cytometry analysis of dual red blood cell populations after bone marrow transplantation.

Flow cytometry represents an alternative method to agglutination assays for the accurate quantification of mixed field populations of erythrocytes observed after bone marrow transplantation. Murine monoclonal antibodies directed against the blood group ABH antigens were selected and processed in order to prepare ready-to-use fluorescent reagents. Anti-A (NaM87-1F6; IgG3), anti-B (NaM9-2E11; IgG3) and anti-H (NaM19-7E11; IgM) were purified, labelled with fluorescein isothiocyanate, and used in a direct flow cytometry assay. Anti-A1 (NaM1-1C9; IgG3) was no longer active after FITC-labelling and then was used in an indirect assay. The agglutination was prevented by formaldehyde pretreatment of erythrocytes. Using artificially-made double populations of erythrocytes, measured values with mixtures of 1-100% of cells were very closely related to expected values, showing both the sensitivity and the accuracy of the method. From careful investigation of a series of bone-marrow transplanted patients, we conclude that engraftments could be demonstrated earlier by flow cytometry than by agglutination, because minor populations (1-10%) of cells could be determined accurately only with labelled reagents. In addition, the disappearance of the donor cells on a long-term follow-up of patients enabled an earlier detection of graft failure in one case. The proposed method provides appreciable help to follow engraftment in patients and may have more general applications for the study of other haemopoietic chimaeras.