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RED CELLS
From the First Department of Internal Medicine,
Fukushima Medical University, Fukushima, Japan, and the Third
Department of Internal Medicine, National Defense Medical College,
Saitama, Japan.
To define the phosphatidylinositol glycan-class A (PIG-A)
gene abnormality in precursor cells and the changes of expression of
glycosylphosphatidylinositol-anchored protein and contribution of
paroxysmal nocturnal hemoglobinuria (PNH) clones with PIG-A gene
abnormalities among various cell lineages during differentiation and
maturation, we investigated CD59 expression on bone marrow CD34+ cells and peripheral granulocytes from 3 patients
with PNH and the PIG-A gene abnormalities in the CD59 Paroxysmal nocturnal hemoglobinuria (PNH) is an
acquired clonal hematologic disorder that is manifested by
complement-mediated hemolysis, venous thrombosis, and bone marrow
failure.1,2 It is well known that PNH erythrocytes consist
of complement-sensitive (PNH II and III) and complement-insensitive
(PNH I) populations as judged by the complement lysis sensitivity (CLS)
test.3 Affected cells in PNH lack
glycosylphosphatidylinositol-anchored proteins (GPI-APs), such as
decay-accelerating factor (DAF)4 and CD59,5 on
their surface membranes due to phosphatidylinositol glycan- class A
(PIG-A) gene abnormalities.6 The absence of these
complement regulatory proteins on PNH erythrocytes causes their
hypersensitivity to complement.7,8 The phenotype of PNH
erythrocytes determined with the CLS test is related to the extent of
the deficiencies of DAF and CD59 on their surfaces.8-10 Thus, single-color or 2-color flow cytometric analysis of erythrocytes has been used both to diagnose PNH and to determine the phenotype of
PNH cells.8-11 Subsequently, GPI-AP-deficient cells were
detected in all hematopoietic lineages (granulocytes, monocytes, T and B lymphocytes, natural killer cells, platelets, and erythrocytes) and
CD34+ cells in patients with PNH.12-15 In
addition, it has been reported that there is a decrease of progenitors
and hypersensitivity of precursors to complement, and a decrease of
CD34+CD59+ and
CD34+CD59 It is unclear how a PNH clone with a PIG-A gene mutation expands in
bone marrow, although some hypotheses, especially negative selection of
PNH clones by cytotoxic T lymphocytes, have been proposed.23 All patients with PNH reported in the past
have been shown to have somatic mutations of the PIG-A
gene,24 which were examined mainly in granulocytes.
However, abnormality of the PIG-A gene in precursor cells from PNH
patients has not been shown directly, although the expression of
GPI-APs in precursors was reported.14,15 Earlier studies
on the PIG-A gene indicated that the blood cells from most PNH patients
have only one PIG-A mutation, suggesting that PNH is
monoclonal.25,26 On the other hand, recent studies
indicated that the blood cells from some PNH patients bear 2 or more
independent PIG-A mutants,27-31 suggesting that PNH is
oligoclonal and that the phenotype of PNH cells is also determined by
the genotype of the PIG-A gene.28,32,33 Recently, we
reported that the distribution of PIG-A gene abnormalities changes
independently among various cell lineages during differentiation and
maturation or during selection, and that PIG-A gene abnormalities determine the phenotype of mature granulocytes, but not of
erythroblasts.34 This may explain part of the
heterogeneous expression of GPI-APs among the various cell lineages
from peripheral blood of PNH patients. However, it is unclear whether a
specific mutation of a PIG-A gene contributes to a particular cell
lineage or whether it is present in a specific stage of maturation,
that is, CD34+ cells capable of self-renewal.
In the present study, to investigate the PIG-A gene abnormality at the
level of precursor cells and the changes in expression of GPI-AP and
contribution of PNH clones with PIG-A gene abnormalities among various
cell lineages during differentiation and maturation of precursor cells
to mature cells in PNH patients, we examined CD59 expression and PIG-A
gene mutations in bone marrow CD34+ cells and peripheral
blood granulocytes from 3 patients with PNH, and compared the PIG-A
gene abnormalities in each population of CD34+ cells with
those of peripheral blood granulocytes, which were sorted into
CD59 Patients and controls
Cell preparation
Monoclonal antibodies A mouse monoclonal antibody to CD59 (3E1, IgG1)5, a mouse monoclonal antibody to CD34 labeled with fluorescein isothiocyanate (HPCA-2, IgG1; Becton Dickinson, San Jose, CA), and a mouse monoclonal antibody to CD45 labeled with peridinin chlorophyll protein (HLe-1, IgG1; Becton Dickinson) were used. A goat antimouse immunoglobulin F(ab')2 fragment labeled with R-phycoerythrin (Dako, Glostrup, Denmark) was used as the second antibody for staining CD59. Irrelevant monoclonal antibodies of the same subclass were used as negative controls.34,35Immunofluorescent staining of bone marrow MNCs and peripheral blood granulocytes, flow cytometry, and cell sorting Immunofluorescent staining of bone marrow MNCs with monoclonal antibodies to CD34, CD45, and CD59 was performed according to the method described by Sutherland et al36 and the manufacturer's recommendation with some modification.34,35 CD34+ cells in bone marrow MNCs were isolated with a FACSVantage (Becton Dickinson) by the gating method that uses both light-scattering parameters and CD34/CD45 fluorescence, as described by Sutherland et al.36 Then, CD59 expression was analyzed with CD34+ cells from the 3 PNH patients and 1 healthy volunteer. The cells were sorted into CD34+CD59 and
CD34+CD59+ fractions using a FACSVantage
equipped with a 488-nm laser (Figure 1).
More than 5 × 103 or 1.2 × 104 cells in
each fraction were sorted into 100 µL PBS-BSA in Eppendorf vials and used for genetic analysis or hematopoietic cell culture, respectively.
Peripheral blood granulocytes were stained with a monoclonal antibody
to CD59 as described previously.34 The stained
granulocytes were gated by forward light scattering and side light
scattering to omit degraded granulocytes, analyzed for CD59 expression,
and then sorted into CD59 Hematopoietic cell culture CD34+CD59+ and CD34+CD59 cells from 2 PNH patients (cases 2 and 3) and 2 healthy volunteers were sorted as described above and cultured (3 × 103 cells/mL) in methylcellulose according
to the method described by Maciejewski et al22 with a
modification. Colonies of early and late erythroid precursors
(erythroid burst-forming units [BFU-Es] and erythroid colony-forming
units [CFU-Es,], respectively) and granulocyte-macrophage precursors
(granulocyte-macrophage colony-forming units [CFU-GMs]) in 2 or 3 dishes each were counted and picked at random using an inverted
microscope after 7 and 14 days of culture and washed in RPMI 1640 and
PBS 3 times. More than 5 × 103 cells were used for PIG-A
gene analysis. Before genetic analysis, parts of the cell suspensions
were fixed with a cytocentrifuge (Shandon Elliott, Runcorn Cheshire,
United Kingdom) and stained with Giemsa solution. All samples contained
more than 95% erythroblasts or granulocytes and monocytes consisting
of more than 90% granulocytes.
gDNA preparation Genomic DNA (gDNA) was prepared with Instagene (Bio-Rad Laboratories, Hercules, CA) according to the manufacturer's recommendation from each sorted CD59, CD59+,
or CD59+/ cell fraction of bone marrow CD34+
cells and peripheral blood granulocytes and from cultured
CD34+ cells.
PCR, cloning, sequence analysis of the PIG-A gene, and direct sequencing of PCR-amplified PIG-A DNA The oligonucleotide primers for polymerase chain reaction (PCR), shown in Table 2 and Figure 2, were designed according to the PIG-A cDNA and gDNA sequences.6,37,38 With PIG-A gDNA obtained from each sorted cell fraction or cultured cells, the coding region of the exon and the intron region flanking the exon were amplified by PCR and sequenced. PCR of genomic PIG-A DNA and cloning were done with the methods34 described previously with some modification. At least 20 genomic PIG-A DNA bacterial clones were sequenced using a BigDye Terminator Cycle Sequencing Ready Reaction Kit (Applied Biosystems, Division of Perkin Elmer, Foster City, CA) and Model 310 Genetic Analyzer (Applied Biosystems). To exclude PCR errors, only PIG-A gene mutations identified in at least 2 independent bacterial clones with 2 or more independent PCR reactions are listed. The frequencies of mutant PIG-A gene clones detected only once were 102 (14.6%) of 700 clones from granulocytes and 80 (12.9%) of 621 clones from CD34+ cells. Also, we sequenced PCR-amplified DNA39,40 from CD34+CD59 cells and
CD59 and CD59+/ granulocytes from case 1, CD34+CD59 cells and CD59
granulocytes from case 2, and CD34+CD59 cells
and CD59 granulocytes from case 3. CD59+
granulocytes from the PNH patients and a healthy volunteer were used
as controls.
Statistical analysis All statistical analyses were performed with the Fisher exact probability test. P < .05 was considered significant.
CD59 expression on peripheral blood granulocytes and bone marrow CD34+ cells The granulocytes from case 1 consisted of CD59,
CD59+/, and CD59+ populations and those in
cases 2 and 3 of CD59 and CD59+ populations
(Figure 3B-D). The granulocytes from a
healthy volunteer consisted of a single positive population (Figure
3A). The proportions of each population in the PNH patients and a
healthy volunteer are shown in Table 1.
The CD34+ cells from the 3 PNH patients consisted of
CD59 Nucleotide sequence analysis of the PIG-A gene and direct sequencing of PCR-amplified PIG-A DNA from sorted peripheral blood granulocytes and bone marrow CD34+ cells The results of nucleotide sequence analyses of the PIG-A gene from each sorted cell fraction of CD34+ cells and granulocytes are shown in Table 3. Differences between the frequencies of the abnormal PIG-A gene in each population sorted from CD34+ cells and from granulocytes of 3 PNH patients were analyzed statistically. There were significant differences between the frequencies of clones with mutation 1-2 from CD34+CD59 cells and CD59+/
granulocytes and mutation 3-2 from CD34+CD59
cells and CD59granulocytes (P < .0001 and
P < .001, respectively). Subsequently, mutations 1-1 in
CD34+CD59 cells (P < .0001) and
CD59 granulocytes (P < .0001), 1-2 in
CD59+/ granulocytes (P < .0001), 2-1 in
CD34+CD59 cells (P < .0001) and
CD59 granulocytes (P < .0001), 3-1 in
CD34+CD59 cells (P < .05) and
CD59granulocytes (P < .05), and 3-2 in
CD59 granulocytes (P < .01) were
predominant compared with the other mutations in each cell population
sorted from each patient. However, there were no significant
differences in the frequencies of mutations 3-1 and 3-2 in
CD59 granulocytes from case 3.
Direct sequence analyses of PCR-amplified DNA showed that mutations
1-1, 1-2, 2-1, 3-1, and 3-2 were clonal genomic abnormalities in
CD34+CD59
PIG-A gene mutations in cultured CD34+ cells from PNH patients The numbers of CFU-E, BFU-E, and CFU-GM colonies from CD34+CD59+ or CD34+CD59 cells from 2 PNH patients (cases 2 and 3) were less or almost the same as those from
CD34+CD59+ cells from 2 healthy individuals
(Table 4). The numbers of colonies of
each precursor cell from CD34+CD59+ cells from
the PNH patients were less than those from
CD34+CD59 cells (Table 4).
As shown in Tables 3 and 4, we found 4 other mutations (mutations 2-2, 2-3, 3-3, and 3-4) in addition to those described above by nucleotide
sequence analyses of the PIG-A gene in cells cultured from
CD34+ cells from the PNH patients. In case 2, there were
significant differences in the frequencies of only the 2-1 mutation in
corresponding colonies from CD34+CD59+ and
CD34+CD59
In this study, we compared both CD59 expression and PIG-A gene
mutations in bone marrow CD34+ cells with those in
peripheral blood granulocytes from 3 patients with PNH. We found
differences in the phenotypes of CD34+ cells and
granulocytes in only one of the PNH patients (case 1). Previously, we
reported differences in the phenotypes in erythroblasts and
erythrocytes from PNH patients,35 suggesting that the
phenotypes determined by GPI-AP expression can change during
differentiation and maturation and the study by Rabessandratana et
al41 supported this finding. In the present study, we found
the PIG-A gene abnormality (mutation 1-2), which is a missense mutation
believed to determine the occurrence of an intermediate population of
PNH cells,29,32 in CD34+CD59 We found a PIG-A gene abnormality (mutation 3-2) only in
CD59 We found that the formation of CD34+CD59 In conclusion, a clonogeneic assay of CD34+ cells using semisolid cultures indicated that the PNH phenotypes determined by expression of GPI-APs on granulocytes are determined at the level of CD34+ cells, that PNH clones with PIG-A gene mutations are oligoclonal in most PNH patients, and that a minor PNH clone is selected or occurs heterogeneously among hematopoietic precursor cell lineages. These results suggest that PNH clones with PIG-A gene abnormalities might contribute qualitatively and quantitatively differentially to specific blood cell lineages during differentiation and maturation of hematopoietic stem cells.
We are grateful to Dr Teizo Fujita and Dr Minoru Takahashi (Department of Biochemistry II, Fukushima Medical University, Japan), Dr Mitsuru Munakata (Department of Pulmonary Medicine, Fukushima Medical University, Japan), Mr Akira Kuwada (Fukushima Technology Center, Japan), and Miss Makoto Yasukawa (Fukushima Technology Center, Japan) for their valuable assistance. Also, we wish to thank Dr Yuuji Sugita (Showa University, Japan) who provided the monoclonal antibody to CD59/membrane attack complex-inhibitory factor.
Submitted January 30, 2001; accepted July 12, 2002.
T.K. and T.S. contributed equally to this work.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Yukio Maruyama, First Department of Internal Medicine, Fukushima Medical University, 1 Hikariga-oka, Fukushima, Fukushima 960-1295, Japan; e-mail: t-shichi{at}fmu.ac.jp.
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© 2002 by The American Society of Hematology.
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  D. Dingli, L. Luzzatto, and J. M. Pacheco Neutral evolution in paroxysmal nocturnal hemoglobinuria PNAS, November 25, 2008; 105(47): 18496 - 18500. [Abstract] [Full Text] [PDF]
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 K. Mochizuki, C. Sugimori, Z. Qi, X. Lu, A. Takami, K. Ishiyama, Y. Kondo, H. Yamazaki, H. Okumura, and S. Nakao Expansion of donor-derived hematopoietic stem cells with PIGA mutation associated with late graft failure after allogeneic stem cell transplantation Blood, September 1, 2008; 112(5): 2160 - 2162. [Abstract] [Full Text] [PDF]
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R. Hu, G. L. Mukhina, S. Piantadosi, J. P. Barber, R. J. Jones, and R. A. Brodsky PIG-A mutations in normal hematopoiesis Blood, May 15, 2005; 105(10): 3848 - 3854. [Abstract] [Full Text] [PDF]
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Abstract
Introduction
