ALBERT

Description: Erythrocytes from patients with paroxysmal nocturnal hemoglobinuria (PNH) are abnormally sensitive to complement. Two membrane proteins, the C8 binding protein (C8bp) and the decay accelerating factor (DAF), which are expressed on normal cells, function to restrict lysis by homologous complement, and both of these proteins are absent from PNH erythrocytes. DAF is anchored to the plasma membrane on normal cells by a phosphatidylinositol linkage. The investigators found that a purified phosphatidylinositol-specific phospholipase C cleaved C8bp from the surface of normal lymphocytes and monocytes. This finding indicates that the abnormal complement sensitivity of PNH erythrocytes arises from a common defect, the inability to attach the phosphatidylinositol- containing anchor that is necessary for the membrane expression of both membrane complement regulatory proteins, the C8bp, and DAF.

Description: Erythrocytes from patients with paroxysmal nocturnal hemoglobinuria (PNH) are abnormally sensitive to complement. Two membrane proteins, the C8 binding protein (C8bp) and the decay accelerating factor (DAF), which are expressed on normal cells, function to restrict lysis by homologous complement, and both of these proteins are absent from PNH erythrocytes. DAF is anchored to the plasma membrane on normal cells by a phosphatidylinositol linkage. The investigators found that a purified phosphatidylinositol-specific phospholipase C cleaved C8bp from the surface of normal lymphocytes and monocytes. This finding indicates that the abnormal complement sensitivity of PNH erythrocytes arises from a common defect, the inability to attach the phosphatidylinositol- containing anchor that is necessary for the membrane expression of both membrane complement regulatory proteins, the C8bp, and DAF.

Description: The decay-accelerating factor (DAF), an integral membrane protein of approximately 75,000 mol wt that regulates the stability of the C3 convertases of the classical and alternative complement pathways, was initially isolated from normal erythrocyte stroma and used to prepare a polyclonal antiserum. Previously, anti-DAF antiserum has been used to immunoprecipitate DAF from surface-labeled normal erythrocytes and to document the deficiency of DAF on the surface of erythrocytes from patients with paroxysmal nocturnal hemoglobinuria, a condition in which erythrocytes express abnormal sensitivity to complement-mediated lysis. DAF has now been demonstrated by cytofluorography with anti-DAF F(ab')2 and fluoresceinated second antibody to be present on the surface of resting polymorphonuclear leukocytes (PMN), monocytes, lymphocytes, and platelets. Populations of PMN, monocytes, and platelets each exhibited a unimodal distribution of fluorescent staining, reflecting uniform cellular expression of DAF antigen, while the lymphocyte population had a skewed pattern of staining, indicating the heterogeneous expression of DAF antigen. For platelets, the shift in mean fluorescence channel observed with cytofluorographic analysis was minimal, but the presence of surface DAF on platelets was demonstrated by specific and saturable anti-DAF F(ab')2 binding. The DAF antigen, analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of dithiothreitol- reduced anti-DAF immunoprecipitates prepared from surface-labeled, isolated populations of cells, presented a single polypeptide chain of approximately 84,000 mol wt for PMN and 75,000 to 80,000 mol wt for monocytes, T and B lymphocytes, and platelets. Thus, the complement regulatory protein, DAF, is expressed on the surface of all major types of circulating blood cells from normal donors.

Description: The presence of cytoplasmic lipid bodies in human eosinophils and the participation of these lipid bodies in the metabolism of arachidonic acid by human eosinophils have been studied. Lipid bodies, structures of roughly spherical shape and variable size within the cytoplasm, were identified with transmission electron microscopy by their shape and variable osmiophilia and by their lack of a limiting membrane. While generally absent from eosinophils of normal peripheral blood, lipid bodies were found in tissue eosinophils and in blood eosinophils from patients with eosinophilia. A role for lipid bodies in arachidonic acid metabolism was determined with eosinophils obtained from two eosinophilic patients. After incubation for 30 to 60 minutes with 3H- arachidonic acid, purified eosinophils took up 50% to 98% of the tritium label. By electron microscopic autoradiography, almost all tritium label was localized to lipid bodies. Only 3.6% of the cell- incorporated tritium label was free arachidonic acid, while 5.8% was neutral lipids and 66% was phospholipid. Thus, most of the tritiated arachidonic acid incorporated by human eosinophils was present in esterified form, predominantly as phospholipids, and almost all of the tritiated lipids were localized ultrastructurally to cytoplasmic lipid bodies. These results provide evidence that lipid bodies of human eosinophils have a role in the cellular metabolism of arachidonic acid.

Description: The presence of cytoplasmic lipid bodies in human eosinophils and the participation of these lipid bodies in the metabolism of arachidonic acid by human eosinophils have been studied. Lipid bodies, structures of roughly spherical shape and variable size within the cytoplasm, were identified with transmission electron microscopy by their shape and variable osmiophilia and by their lack of a limiting membrane. While generally absent from eosinophils of normal peripheral blood, lipid bodies were found in tissue eosinophils and in blood eosinophils from patients with eosinophilia. A role for lipid bodies in arachidonic acid metabolism was determined with eosinophils obtained from two eosinophilic patients. After incubation for 30 to 60 minutes with 3H- arachidonic acid, purified eosinophils took up 50% to 98% of the tritium label. By electron microscopic autoradiography, almost all tritium label was localized to lipid bodies. Only 3.6% of the cell- incorporated tritium label was free arachidonic acid, while 5.8% was neutral lipids and 66% was phospholipid. Thus, most of the tritiated arachidonic acid incorporated by human eosinophils was present in esterified form, predominantly as phospholipids, and almost all of the tritiated lipids were localized ultrastructurally to cytoplasmic lipid bodies. These results provide evidence that lipid bodies of human eosinophils have a role in the cellular metabolism of arachidonic acid.

Description: A cDNA clone encoding the human monocyte antigen CD14 was isolated by transient expression in COS cells of a cDNA library prepared from phorbol diester-treated HL60 cells. RNA blot analysis showed abundant expression of a single mRNA species in mature monocytes and an increased expression of the mRNA following induction of differentiation in leukemic cell lines. The DNA blot hybridization pattern was consistent with a single-copy gene. The predicted amino acid sequence lacks the characteristic transmembrane domain and stop transfer motif of conventionally anchored membrane proteins. COS cells transfected with the CD14 cDNA released virtually all CD14 protein in soluble form following treatment with glycosyl phosphatidylinositol-specific phospholipase C, and CD14 immunoreactivity was absent from the affected monocytes of a patient with paroxysmal nocturnal hemoglobinuria (PNH). The data show that, to the limit of experimental sensitivity, all monocyte CD14 is joined to the plasma membrane by a phosphatidylinositol phospholipid.

Description: A cDNA clone encoding the human monocyte antigen CD14 was isolated by transient expression in COS cells of a cDNA library prepared from phorbol diester-treated HL60 cells. RNA blot analysis showed abundant expression of a single mRNA species in mature monocytes and an increased expression of the mRNA following induction of differentiation in leukemic cell lines. The DNA blot hybridization pattern was consistent with a single-copy gene. The predicted amino acid sequence lacks the characteristic transmembrane domain and stop transfer motif of conventionally anchored membrane proteins. COS cells transfected with the CD14 cDNA released virtually all CD14 protein in soluble form following treatment with glycosyl phosphatidylinositol-specific phospholipase C, and CD14 immunoreactivity was absent from the affected monocytes of a patient with paroxysmal nocturnal hemoglobinuria (PNH). The data show that, to the limit of experimental sensitivity, all monocyte CD14 is joined to the plasma membrane by a phosphatidylinositol phospholipid.

Description: The Charcot-Leyden crystal (CLC) protein is a unique constituent of eosinophils and basophils. This protein forms the hexagonal bipyramidal crystals observed in tissues at sites of eosinophil accumulations, possesses lysophospholipase activity (lysolecithin acylhydrolase E.C.3.1.1.5), and comprises an estimated 7% to 10% of total eosinophil protein. The ultrastructural localization of CLC protein was studied in mature peripheral blood eosinophils from normal donors and from patients with the idiopathic hypereosinophilic syndrome. Subcellular localization was evaluated by immunoelectron microscopy using eosinophils, both from buffy coat and purified cell suspensions, that were fixed by a variety of methods. Immunochemical detection of CLC protein employed rabbit antiserum to eosinophil CLC protein, affinity chromatography-purified monospecific IgG antibodies, and postembedding immunogold techniques. Controls for specificity included (1) omission of the primary antibody to CLC protein and (2) substitution of primary antibody with a nonimmune preimmunization serum, a protein A-purified nonimmune IgG, or a protein A-purified nonreactive IgG prepared from solid-phase CLC protein-Sepharose-absorbed anti-CLC antiserum. CLC protein was localized to a minor (approximately 5%) subpopulation of eosinophil granules. These membrane-bound cytoplasmic granules were large (greater than 0.5 mu), were devoid of crystalloid inclusions, and were morphologically compatible with persisting eosinophil primary granules. The crystalloid-containing, large, specific granules did not stain for CLC protein. Insufficient numbers of small dense granules, lipid bodies, and vesiculotubular structures were present to adequately evaluate their potential as additional sites for the subcellular localization of CLC protein. The cellular specificity of the immunogold localization of CLC protein in the eosinophil was affirmed by the absence of staining in neutrophils and lymphocytes present in the same sections. The ultrastructural immunogold localization of CLC protein (lysophospholipase) to a large, crystalloid-free granule in mature circulating eosinophils supports the persistence of a distinct “primary” granule population that serves as a major intracytoplasmic repository for this enzyme.