Production and characterization of lymphoblastoid cell lines with the paroxysmal nocturnal hemoglobinuria phenotype

Paroxysmal nocturnal hemoglobinuria (PNH) is an acquired hemolytic disorder caused by a somatic mutation in a hematopoietic stem cell. The fact that, in some cases, not only myeloid but also lymphoid cells are affected suggests that the mutation has occurred in a multipotent stem cell. By studying the expression of CD59 antigen (membrane inhibitor of reactive lysis) and of decay accelerating factor (DAF) on the lymphocytes of 16 patients with PNH, we found an abnormal population of lymphocytes (with absent CD59 and DAF) in 10 cases. From 4 of these patients we were able to produce Epstein-Barr virus-immortalized lymphoblastoid cell lines (LCLs) that have a PNH phenotype (absent CD59, DAF, and CD48). PNH LCL cells have apparently normal DAF messenger RNA despite not having DAF on their surface. These cell lines will be a valuable resource for further investigation of the defect or defects underlying PNH.     

Paroxysmal nocturnal hemoglobinuria (PNH) deficiency of major complement-regulatory membrane proteins on erythrocytes]

The significance of the deficiency of the major complement-regulatory membrane proteins, decay-accelerating factor (DAF) and CD59, to the lysis of paroxysmal nocturnal hemoglobinuria (PNH) red blood cells was investigated. DAF and CD59 were demonstrated to be deficient simultaneously on affected PNH red blood cells (PNH-III) by two-color FACS analysis. At least in some patients with PNH, PNH-I was also revealed to be deficient partially in DAF. Purified DAF and CD59 ameliorated the complement sensitivity of PNH red blood cells, partially and completely, respectively. Functional blocking of these molecules on nomrla human red cells by monoclonal antibodies to DAF and CD59 rendered A or AB type blood cells complement-sensitive but not O or B blood type blood cells. The differences of complement-sensitivity among blood types were revealed to reside on the step of binding of C9 to C5b-8, i. e. C9 can bind to C5b-8 more on A type blood cells than on O type blood cells. We conclude that the deficiency of DAF and CD59 play a major role for the complement sensitivity of PNH red blood cells and that other factors reported to be deficient in PNH do less than these two proteins.     

Defective and normal haematopoietic stem cells in paroxysmal nocturnal haemoglobinuria

Summary. The expression of decay-accelerating factor (DAF or CD55) and CD59 during haematopoietic cell development in bone marrow aspirates of two patients with paroxysmal nocturnal haemoglobulinuria (PNH) was compared with that in normal bone marrow by five-dimensional flow cytometry. In contrast to early uncommitted haematopoietic progenitor cells (CD34+, CD38-) in normal bone marrow which uniformly express DAF and CD59, the majority of CD34+, CD38- cells in both patients' marrow exhibited the absence of the two proteins. In both specimens, however, subpopulations of CD34+, CD38- cells expressing DAF and CD59 were detectable, indicative of the presence of two lines of haematopoiesis, one abnormal and the other normal. Concurrent abnormal and normal haematopoietic development was further evident by the presence of subpopulations of DAF-, CD59- and DAF+, CD59+ cells along the differentiation and maturation pathways of the myeloid (CD33+, CD15- → CD33+→++, CD15+), the erythroid (CD45^dim, CD71^dim→ CD45-, CD71++), and the B-lymphoid cell lineages (CD10++, CD20- → CD10-, CD20++). While the majority of cells differentiating into and maturing along each cell lineage lacked DAF and CD59, the majority of mature B (CD20++, CD10-) and T-lymphocytes (CD3+) expressed both proteins suggestive of the presence of lymphocytes with a long life span which were generated from normal haematopoietic progenitors before the onset of the disease. The detection of distinct sets of CD34+, CD38- →+ progenitor cells which are DAF+, CD59+ or DAF-, CD59- in marrow of PNH patients has relevance for the treatment of PNH. Cells with the phenotype CD34+, CD38-, DAF+, CD59+ are capable of self renewal and represent potential candidates for autologous bone marrow transplantation following depletion of CD34+, CD38-, DAF-, CD59- cells.     

Peripheral blood harvest of unaffected CD34+ CD38- hematopoietic precursors in paroxysmal nocturnal hemoglobinuria

Paroxysmal nocturnal hemoglobinuria (PNH) arises from somatic mutation of a bone marrow progenitor that disrupts glycosylinositol phospholipid (GPI) anchoring of cell surface proteins. We recently characterized the expression of GPI-anchored decay acclerating factor (DAF) and CD59 during hematopoietic development in PNH marrow. We found that, although a subset of early hematopoietic precursors identified by the CD34+CD38- phenotype exhibits normal DAF and CD59 expression, DAF and CD59 are absent on the majority of CD34+CD38- cells. Pluripotent CD34+CD38- hematopoietic stem cells normally circulate in the peripheral blood and can be collected by apheresis, cryopreserved, and later used for reconstitution of hematopoiesis. In this study, we examined the phenotypes of CD34+ cells that are released into the blood of PNH patients. Analyses of apheresis samples from three affected individuals showed discrete populations of circulating DAF+CD59+CD34+ and DAF-CD59- CD34+ cells. Variable proportions of CD34+CD38- cells were present within the peripheral blood CD34+ cells of each patient, but in all three cases the DAF+CD59+CD34+CD38- cell subset subset. Because CD34+ cells lacking CD38 antigen are highly enriched for self-renewing hematopoietic stem cells, these findings indicate that apheresis samples can serve as a source of unaffected stem cells for autologous marrow transplantation of PNH patients.     

Deficiency of an erythrocyte membrane protein with complement regulatory activity in paroxysmal nocturnal hemoglobinuria.

Paroxysmal nocturnal hemoglobinuria (PNH) is an acquired hemolytic anemia in which the erythrocytes are abnormally sensitive to lysis by complement. A functional deficiency of membrane-associated complement regulators has been demonstrated on PNH erythrocytes. The two factor H-like proteins, the C3b receptor (CR1) and the decay-accelerating factor (DAF), were isolated from normal human erythrocytes, and specific antisera were prepared. Selective inhibition of the two proteins on normal erythrocytes by the antisera demonstrated (i) that the factor responsible for accelerated decay of erythrocyte-bound C3 convertase is DAF and (ii) that the cofactor required for inactivation of erythrocyte-bound C3b by factor I is CR1. PNH erythrocytes were deficient in both of these activities. Erythrocytes deficient in CR1, which were obtained from an apparently healthy individual, exhibited normal DAF activity but no factor I cofactor activity. These cells were not susceptible to complement-mediated lysis in acidified human serum, whereas PNH erythrocytes and Pronase-treated human erythrocytes (which lack DAF and CR1 activities) were lysed by this treatment. It is suggested that the protein primarily responsible for preventing complement activation on normal human erythrocytes is DAF. AMr 73,000 protein isolated from the normal erythrocyte membranes of one PNH patient by using anti-DAF IgG was largely absent from the abnormal erythrocytes of this individual, suggesting that PNH cells lack the DAF protein. CR1 antigen, however, was present on the abnormal PNH erythrocytes. The results suggest that the primary molecular defect underlying the clinical manifestations of PNH may be the lack of the membrane-associated DAF protein and that the abnormal cells may also exhibit impaired CR1 function.     

Discordant and heterogeneous expression of GPI-anchored membrane proteins on leukemic cells in a patient with paroxysmal nocturnal hemoglobinuria

We performed a flow cytometric analysis using monoclonal antibodies to decay accelerating factor (DAF) and CD59/membrane attack complex inhibitory factor (CD59/MACIF) in order to investigate the leukemic cells and erythrocytes from a patient with paroxysmal nocturnal hemoglobinuria (PNH) who developed acute myelocytic leukemia. In May 1990, the leukemic cells comprised 70% of the mononuclear cells in the bone marrow and 76% of those in the peripheral blood. They consisted of a mixture of positive and negative populations, including single DAF- positive cells. In August 1990, almost 100% of the peripheral mononuclear cells were leukemic blasts, and these consisted of a single population with reduced DAF expression. Single-color flow cytometric analysis showed that the leukemic cells lacked CD59/MACIF, while control leukemic cells (n = 3) expressed both DAF and CD59/MACIF. Leukemic blasts from this patient and six control patients expressed lymphocyte function-associated antigen 3 and FcIII receptors (CD 16) both before and after treatment with phosphatidylinositol-specific phospholipase C. The patient's erythrocytes lacking DAF and CD59/MACIF expression corresponded to the proportion of complement-sensitive cells at the onset of acute leukemia. These DAF- and CD59/MACIF-deficient erythrocytes disappeared almost completely with progression of the leukemia. In conclusion, it appears that the expression of glycosylphosphatidylinositol-linked membrane proteins by leukemic cells was heterogeneous and discordant in our patient, and that the leukemic cells were derived from the PNH clone because of their deficiency of CD59/MACIF. It is also suggested that DAF could compete more effectively than CD59/MACIF for a limited number of anchor molecules available on the proliferating leukemic cells.     

Heterogenous expression of decay accelerating factor and CD59/membrane attack complex inhibition factor on paroxysmal nocturnal haemoglobinuria (PNH) erythrocytes

In order to clarify the characterization of phenotypes of paroxysmal nocturnal haemoglobinuria (PNH) erythrocytes (E), we analysed the expression of decay accelerating factor (DAF) and CD59/membrane attack complex inhibition factor (MACIF) on the membrane surface of PNH-E by means of the flow cytometric method using anti-DAF and/or CD59/MACIF monoclonal antibodies in nine PNH-patients. In two-colour analysis, this expression of PNH-E was classified into three fractions; negative, intermediate and positive according to intensity. The negative fraction was classified into two groups; one group an exclusively negative population, and the other a negative population having slightly DAF-positive E. The intermediate fraction was recognized on PNH-E of cases with PNH II-E and extremely heterogenous. In the positive fraction, this expression was almost the same as on normal E except for case 8. In single-colour analysis for DAF or CD59/MACIF, three fractions were classified as well as the definition in two-colour analysis. In single-colour analysis, the expression on PNH-E was also heterogenous in each fraction and among PNH-patients. However, the intermediate fraction for CD59/MACIF was not found on PNH-E of cases without PNH II-E, although intermediate fraction for DAF was recognized on PNH-E of some cases with PNH III-E in addition to those with PNH II-E. The results suggest that expression of CD59/MACIF and DAF on the membrane surface of PNH-E phenotypes is heterogenous and varies among PNH patients.     

Markedly high population of affected reticulocytes negative for decay- accelerating factor and CD59 in paroxysmal nocturnal hemoglobinuria

Paroxysmal nocturnal hemoglobinuria (PNH) blood cells lack glycosylphosphatidylinositol-anchored membrane proteins such as decay- accelerating factor (DAF) and CD59. This lack is of diagnostic value in PNH. Because reticulocytes in PNH are not yet well characterized, we analyzed reticulocytes obtained from 12 patients with PNH and from 5 healthy volunteers by two-color flow cytometry with a membrane- permeable fluorescent dye, thiazole orange, to identify reticulocytes and monoclonal antibodies to DAF and CD59. Healthy individuals had no affected cells. In all patients, the population of affected reticulocytes negative for DAF and CD59 was markedly higher than the population of affected erythrocytes. Moreover, the population of affected erythrocytes became obviously low in patients who received transfusions and suffered from hemolytic precipitation, whereas the population of affected reticulocytes was unchanged. The persistently high population of affected reticulocytes, despite cytolytic exclusion and an inherently short lifetime, might possibly be explained by relative reticulocytosis caused by an anemia-induced feedback stimulation of erythropoiesis in PNH. Thus, affected reticulocytes could be a reliable marker for the diagnosis of PNH and for the evaluation of erythropoiesis by PNH stem cell.     

Complement sensitivity of erythrocytes in a patient with inherited complete deficiency of CD59 or with the Inab phenotype

We investigated the complement sensitivity of erythrocytes from three patients, one with inherited complete deficiency of CD59, one with the Inab phenotype, and one with paroxysmal nocturnal haemoglobinuria (PNH). The complement lysis sensitivity units on the erythrocytes were 11.7, 4.6, and 47.6 for inherited CD59 deficiency, Inab phenotype, and PNH, respectively. Two-colour flow cytometric analysis showed that the erythrocytes from the three patients consisted of a single population negative for CD59, negative for decay accelerating factor (DAF), and negative for both proteins, respectively. In addition, only the Inab phenotype patient had no haemolysis in vivo. These facts suggest that CD59 deficiency plays a more important role than DAF deficiency in complement-mediated haemolysis in vitro and in vivo, and that deficiency of both proteins, but not CD59 or DAF alone, causes complement sensitivity corresponding to that of PNH III erythrocytes in vitro.     

Estimation of PI-bound proteins on blood cells from PNH patients by quantitative flow cytometry

The phosphatidylinositol (PI) bound proteins (acetylcholin-esterase (ACE), decay accelerating factor (DAF), leucocyte function antigen type 3 (LFA-3) and Fc-receptor type III (FcRIII] were estimated by flow cytometry on blood cells from four patients with paroxysmal nocturnal haemoglobinuria (PNH), nine patients with 'non-PNH' haemolytic anaemia, four patients with aplastic anaemia and a reference group of 15 healthy individuals to assess the applicability of flow cytometric measurements in the clinical mapping of the PNH defect. Estimation of DAF on granulocytes or monocytes offered the highest diagnostic sensitivity and specificity and may constitute an easy screening method for the PNH defect. One PNH patient had a negative Ham's test at the time of study and normal or near normal levels of PI-bound proteins on erythrocytes, but reduced expression of DAF and FcRIII on granulocytes and DAF on monocytes. The analytical and biological coefficient of variation for flow cytometric estimation of PI-bound proteins was in the range of 4.8-13% and 12-24%, respectively. Blood samples should be analysed without delay, since storage produced spuriously high results. The results were expressed as molecules per cell after calibration with commercially available standards and validated by comparison with previously reported results obtained by other methods. It is proposed that this way of reporting flow cytometric results should be generally adopted to facilitate comparison of results between laboratories.     

The erythrocytes in paroxysmal nocturnal haemoglobinuria of intermediate sensitivity to complement lysis

The sensitivity to lysis by complement of the erythrocytes of 56 patients with paroxysmal nocturnal haemoglobinuria (PNH) was compared to the membrane expression of decay accelerating factor (DAF, CD55), membrane inhibitor of reactive lysis (MIRL, CD59) and acetylcholinesterase (AChE). Most patients (36/50 72% in whom the analysis could be made) appeared to have erythrocytes of intermediate sensitivity to complement in the blood. These cells appeared as a discrete population of cells (PNH II cells), as a 'tail' of cells slightly less sensitive than the predominant PNH III cells (previously called PNH IIIb cells), or as a continuous spectrum of cells sensitive to complement. The PNH III cells totally lacked all three proteins (DAF, MIRL, AChE) by flow cytometric analysis whereas PNH I cells appeared to have normal or nearly normal amounts of each. The cells of intermediate sensitivity (PNH II) had coordinately decreased expression of all three proteins; the level of expression of DAF and MIRL paralleled the sensitivity of the cells to the haemolytic action of complement.     

Expression of decay-accelerating factor and CD59 in lymphocyte subsets of healthy individuals and paroxysmal nocturnal hemoglobinuria patients

The expression of phosphatidylinositol (PI)-anchored complement-regulatory membrane proteins on circulating blood cells has been well clarified; however, the PI proteins on lymphocyte subsets have not been fully analyzed yet. We examined the expression of decay-accelerating factor (DAF) and CD59 on the T lymphocytes (CD2^?, CD3⁺, CD4^?, and CD8^?) and CD20⁺ B lymphocytes in ten healthy volunteers and 12 paroxysmal nocturnal hemoglobinuria (PNH) patients by cytofluorometry. In healthy controls, each subset of lymphocytes showed a small population of cells weakly positive and a large population of cells strongly positive for DAF and CD59, while erythrocytes showed a single population of cells positive for the PI proteins. The two-population expression of DAF was most distinctive in CD8^? T cells among the subsets. In PNH, each subset of lymphocytes showed a moderately higher population of cells weakly positive and a smaller population of cells strongly positive for the membrane proteins compared with those in the healthy controls. Moreover, in some PNH cases, a negative population for the proteins was found in all subsets. Thus the analysis of PI-anchored proteins on lymphocyte subsets (especially CD8^? T cells) was considered to be of diagnostic value in PNH patients who receive blood transfusion after hemolytic attack of affected erythrocytes. Furthermore, the two-population expression of PI proteins in normal lymphocytes suggests that membrane PI protein would be a new subset marker of lymphocytes.     

Diagnosis of paroxysmal nocturnal haemoglobinuria by phenotypLc analysis of erythrocytes using two-colour flow cytometry with monoclonal antibodies to DAF and CD59/MACIF

Summary We investigated the relationship between the complement lysis sensitivity test and two-colour flow cyto-metric analysis using monoclonal antibodies to decay accelerating factor (DAF) and CD59/membrane attack complex inhibitory factor (MACIF) in patients with paroxysmal nocturnal haemoglobinuria (PNH) and other haematological diseases.
Flow cytometry showed that all 59 PNH patients had two or three erythrocyte populations, while all 74 patients with other haematological diseases and all 31 healthy volunteers had a single erythrocyte population. We compared the percentage of PNH III erythrocytes in the lysis test with the percentage of negative cells shown by flow cytometry in 52 PNH patients, and found a significant correlation ( r =0–960, P<0.001). However, in 13 patients the erythrocyte pheno-types did not correspond in both tests. This was generally related to difficulty of detecting PNH II erythrocytes in the lysis test.
In the PNH patients the ranges of mean fluorescence intensity for the negative, intermediate and positive erythrocyte populations were respectively 1.1–2.5. 2.2–29, and 61–600 for CD59IMACIF positivity and 1.9–7.2, 3.6–22, and 31–350 for DAF positivity. In contrast, the mean intensities in healthy volunteers ranged from 190 to 720 for CD59/ MACIF and from 150 to 350 for DAF.
These findings suggest that PNH can be diagnosed and phenotypic analysis of PNH erythrocytes can be performed by respectively assessing the fluorescence profiles and mean fluorescence intensities of both proteins using flow cytometry. Flow cytometry may provide a superior diagnostic method to the traditional tests for PNH.     

Longer in vivo survival of CD59- and decay-accelerating factor-almost normal positive and partly positive erythrocytes in paroxysmal nocturnal hemoglobinuria as compared with negative erythrocytes: a demonstration by differential centrifugation and flow cytometry.

Three populations of erythrocytes have been shown by flow cytometric analysis on complement regulatory proteins: CD59 and decay-accelerating factor (DAF) on erythrocytes in paroxysmal nocturnal hemoglobinuria (PNH). CD59 and DAF in PNH may be completely deficient in CD59- and DAF-negative erythrocytes, they may be decreased varyingly in partly positive erythrocytes, and they may be approximately normal in almost normal positive erythrocytes. Control erythrocytes are always CD59- and DAF-normal positive. CD59- and DAF-negative erythrocytes have been shown to be most sensitive to complement lysis in vitro. However, it has not yet been elucidated whether CD59- and DAF-almost normal positive and partly positive erythrocytes in a patient have a longer in vivo survival than negative erythrocytes. Blood from controls and PNH patients was separated in five fractions by differential centrifugation. CD59 and DAF on the fractionated erythrocytes were determined by flow cytometry using specific antibodies. Ratios of CD59- and DAF-almost normal positive and partly positive cells to negative erythrocytes were increased progressively from the top fraction to the bottom. The erythrocytes in the top fraction are younger and reticulocyte-rich, while those in the bottom are older and reticulocyte-poor. Hence, the present results indicate that CD59- and DAF-partly positive erythrocytes as well as almost normal positive erythrocytes in patients may have a longer in vivo survival than negative erythrocytes.     

Robust in vitro replication of Plasmodium falciparum in glycosyl-phosphatidylinositol-anchored membrane glycoprotein-deficient red blood cells

Red blood cells (RBCs) infected with Plasmodium falciparum are protected from complement-mediated lysis by surface membrane glycosyl-phosphatidylinositol (GPI)-anchored proteins, which include decay accelerating factor (DAF or CD55) and CD59. To determine if P. falciparum avoids or replicates less efficiently in GPI protein-deficient cells at a higher risk for complement-mediated lysis, we compared P. falciparum infectivity among control RBCs with those from subjects with paroxysmal nocturnal hemoglobinuria (PNH), a condition in which RBCs express variable levels of DAF (negative and positive) and CD59 (negative [-], intermediate [I], and high [H]). Co-cultures of 19 matched samples of control and PNH RBCs were infected with P. falciparum to directly compare parasitic invasion. Each PNH RBC sample was then assessed for P. falciparum infectivity across the spectrum of GPI protein deficiency. Identification methods included biotin-streptavidin for RBC populations, fluorescein isothiocyanate-labeled antibodies to DAF and CD59, hydroethidine for parasite DNA, and flow cytometry. The mean +/- SD parasitemias in co-cultured PNH and control RBCs were 24.7 +/- 6.9% versus 21.0 +/- 5.9% (P = 0.12). For individual PNH samples, parasitemias were significantly higher in DAF (-) cells versus DAF (+) cells (25.0 +/- 8.9% versus 19.1 +/- 8.7%; P < 0.001) and in CD59 (-) cells versus I/H cells (22.5 +/- 6.4% versus 17.6 +/- 4.2%; P < 0.0003). Across the CD59 spectrum, mean parasitemias were highest in CD59 (-) cells (24.5 +/- 6.4%), followed by CD59-H cells (19.5 +/- 5.4%), and CD59-I cells (16.4 +/- 4.8%). Expression of DAF in 12 (63%) of 19 infected PNH samples was reduced. Thus, P. falciparum does not selectively avoid RBCs with fewer GPI proteins and parasite replication in PNH cells is at least as robust as in normal RBCs.     

Structural and functional differences between decay-accelerating factor and red cell acetylcholinesterase

The abnormal erythrocytes in paroxysmal nocturnal hemoglobinuria, both PNH II (the moderately abnormal cells) and PNH III (the markedly abnormal cells), lack both acetylcholinesterase (AChE) activity and decay-accelerating factor (DAF) activity. Both of these activities are found on glycoprotein molecules with a molecular weight of about 70 Kd. To demonstrate that these two activities are in fact on different proteins, we have shown that binding to normal red cells of antibody to DAF does not inhibit the subsequent binding of monoclonal antibody to AChE nor AChE activity. Inhibition of DAF activity by polyclonal antibody increases the susceptibility of normal erythrocytes to lysis by complement but inhibition of AChE activity by antibody does not. The rate of decay of the C3 convertase complex of the classical pathway of complement activation was inhibited by DAF added in the fluid phase but not by AChE. When DAF was exhaustively immunoprecipitated from a solution of the erythrocyte membrane proteins, AChE remained and vice versa. These studies indicate that acetylcholinesterase and decay-accelerating factor are two different proteins, both of which are lacking on PNH II and PNH III erythrocytes.     

Deficiency of glycosyl-phosphatidylinositol-linked membrane glycoproteins of leukocytes in paroxysmal nocturnal hemoglobinuria, description of a new diagnostic cytofluorometric assay

Paroxysmal nocturnal hemoglobinuria (PNH) is a disease that affects not only red cells, but other blood cells as well. The common defect is supposed to be an acquired deficiency of glycosyl-phosphatidylinositol (GPI)-anchored membrane proteins, which may be present already at the hematopoietic stem cell level. Recently, a panel of monoclonal antibodies (MoAbs) has become available directed against various GPI-linked membrane proteins. This makes it possible to study various cell lineages for the deficiency of such proteins in PNH in more detail. Using cytofluorography, we could show that the granulocytes of 20 different PNH patients miss not only GPI-linked FcRIII (CD16 antigen), but also three other GPI-linked proteins, ie, CD24 antigen, CD67 antigen and a granulocyte-specific 50 to 80 Kd antigen. The affected granulocytes were not only neutrophils but also eosinophils, as was found in a more detailed analysis of three patients. Moreover, in all 10 PNH patients tested, the monocytes were found to be deficient for the GPI-linked CD14 antigen, and we found with CD24 and CD55 (DAF) antibodies that lymphocytes may be involved as well. However, abnormal B and T lymphocytes were detected only in a subset of patients (2 of 10 tested). The uniform deficiency of GPI-linked proteins of granulocytes allows the introduction of a new diagnostic cytofluorometric assay for PNH with MoAbs against GPI-linked granulocytic antigens. This test was positive in all PNH patients studied and not in a group of 40 control patients or 50 normal donors, with the exception of three of 16 aplastic anemia (AA) patients. In the three AA patients, subpopulations (10% to 20%) of PNH granulocytes could be detected, whereas these patients had a negative acidified serum (Ham) test. This indicates that the new test is more sensitive than the Ham test and allows the early diagnosis of PNH in AA. An advantage of the neutrophil assay is that, in contrast to the Ham test, it is not influenced by recent red-cell transfusions. Moreover, it is possible to quantify the number of affected cells by single cell analysis.     

Interleukin-2-dependent T-cell lines established from paroxysmal nocturnal hemoglobinuria patients

Peripheral blood T lymphocytes obtained from two patients with paroxysmal nocturnal hemoglobinuria (PNH) were immortalized with human T-lymphotropic virus type 1 (HTLV-1). These cells showed interleukin-2 (IL-2)-dependent cell growth in culture. Cell surface analysis showed that they had the phenotype of a helper/inducer T subset that was positive for CD2, CD3, and CD4, but negative for CD8, similar to adult T-cell leukemia cells induced by HTLV-1. These cell lines lacked glycosylphosphatidylinositol (GPI)-anchored proteins, CDw52, CD55 (decay-accelerating factor; DAF), and CD59 on the cell surface, whereas intracellular DAF protein was detected. These T-subset cell lines with a PNH phenotype did not synthesize GPI anchor, whereas a control cell line, similarly prepared from the T cells of a healthy volunteer, produced the anchor. The control cells expressed CDw52, DAF, and CD59 on the cell surface and showed the phenotype of a helper/inducer subset. Southern blot analysis confirmed the clonality of each cell line. These CD4+ T-cell lines with a PNH phenotype and a subset-matched control counterpart could be a useful model for PNH investigation.     

Release of C8 binding protein (C8bp) from the cell membrane by phosphatidylinositol-specific phospholipase C

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.     

The use of monoclonal antibodies and flow cytometry in the diagnosis of paroxysmal nocturnal hemoglobinuria

We have characterized the erythrocytes, granulocytes, and platelets of 54 patients with paroxysmal nocturnal hemoglobinuria (PNH) with antibodies to glycosylphosphatidylinositol-anchored proteins (anti- CD55, anti-CD59, and anti-CD16) and flow cytometry to establish the usefulness of this technique in the diagnosis of this disorder. All patients demonstrated either completely (PNH III) or partially (PNH II) deficient red cells and granulocytes. Anti-CD59 best demonstrated PNH II red cells, which were present in 50% of the patients. The proportion of abnormal granulocytes was usually greater than the proportion of abnormal red cells; 37% of the patients had >80% abnormal granulocytes. Anti-CD55 did not delineate the erythrocyte populations as well as did anti-CD59. Either anti-CD55 or anti-CD59 could be used equally well to analyze granulocytes; anti-CD16 did not demonstrate cells of partial deficiency. Platelets could not be used for detailed analysis as the normal and abnormal populations were not well distinguished. Flow cytometry of erythrocytes using anti-CD59 or of granulocytes using either anti-CD55 or anti-CD59 provides the most accurate technique for the diagnosis of paroxysmal nocturnal hemoglobinuria; it is clearly more specific, more quantitative, and more sensitive than the tests for PNH that depend upon hemolysis by complement (the acidified serum lysis [Ham] test, the sucrose lysis test, and the complement lysis sensitivity [CLS] test).