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Prepublished online as a Blood First Edition Paper on July 18, 2002; DOI 10.1182/blood-2002-06-1669.
IMMUNOBIOLOGY
From the Department of Immunoregulation, Research
Institute for Microbial Diseases, Department of Experimental Genome
Research, Genome Information Research Center, and Departments of
Dermatology and Environmental Medicine, Graduate School of Medicine,
Osaka University, Suita, Osaka, Japan.
Paroxysmal nocturnal hemoglobinuria (PNH) is a hematopoietic stem
cell disorder in which clonal cells defective in
glycosylphosphatidylinositol (GPI) biosynthesis are expanded, leading
to complement-mediated hemolysis. PNH is often associated with bone
marrow suppressive conditions, such as aplastic anemia. One
hypothetical mechanism for the clonal expansion of GPI Paroxysmal nocturnal hemoglobinuria (PNH) is an
acquired hematopoietic stem cell disorder characterized by the presence
of clonal blood cells deficient in glycosylphosphatidylinositol
(GPI)-anchored proteins. A somatic mutation of the PIGA
gene, which is involved early in the biosynthesis of the GPI
anchor,1 is responsible for the
deficiency.1-3 Because GPI acts as a membrane anchor for
many cell surface proteins,4 a loss of function of
PIGA results in the loss of all the GPI-anchored proteins
from the blood cell surface. PIGA is X-linked; therefore,
one hit of somatic mutation in PIGA causes GPI anchor
deficiency in the hematopoietic stem cell.2 Clonal cells
derived from the mutant hematopoietic stem cell occupy a big fraction
of hematopoietic cells.5
The characteristic clinical triad of PNH includes hemolysis, venous
thrombosis, and bone marrow failure.6,7 The activation of
complement leads to the lysis of red blood cells deficient in the
GPI-anchored proteins CD59 and CD55 that protect host cells from the
attack by complement.4,5 An impaired regulation of
complement activation may also be relevant to venous
thrombosis.6,7 Bone marrow failure may be due to an
autoimmune mechanism as thought to operate in idiopathic aplastic
anemia (AA) that is often associated with PNH.6,7
Clonal expansion of cells derived from the mutant hematopoietic
stem cell is critical for clinical manifestation of PNH. The mechanism,
however, has not been elucidated. To test whether a defective
PIGA alone can cause the clonal expansion, we as well as
Rosti and colleagues disrupted the mouse Piga gene, a
homologue of PIGA, in embryonic stem cells and raised
chimeric mice bearing GPI To overcome these problems, we made PNH model mice bearing
GPI Then, there have been 2 hypotheses about the second factor. One holds
that the mutant clone itself gains an intrinsic ability to expand, a
growth phenotype, by one or more additional genetic modifications. The
other holds that the mutant clone is selected under the affected
environment.6 As to the latter hypothesis, it was
suggested that the affected environment may be an autoimmune process,14 because this is a widely accepted pathogenetic
mechanism in idiopathic AA.15 The effector responsible in
AA has not been clarified, but there are reports that CD4+
T-cell clones capable of killing autologous hematopoietic progenitor cells can be generated by culturing T cells of AA patients with autologous hematopoietic progenitor cells.16,17 PNH, like
AA, is reported to be strongly associated with the HLA haplotype
DR218,19 and skewed usage of T-cell receptor (TCR) V Mice
Peptides and antibodies
Cell lines A vector for the expression of GPI-anchored OVA (GPI-OVA) was constructed by 4 parts ligation of an EcoRI-PstI fragment encoding the N-terminal signal sequence of human CD59, a polymerase chain reaction (PCR)-amplified fragment corresponding to nucleotides 415-1161 of chicken OVA cDNA (to which PstI and XhoI sites were attached), an XhoI-NotI fragment encoding the human CD59 GPI attachment signal, and EcoRI- and NotI-cut pME18sf-neo, a mammalian expression plasmid. A vector for the expression of transmembrane OVA (TM-OVA) was constructed connecting EcoRI- and XbaI-cut pME18sf-neo, the same first 2 fragments used to generate the GPI-OVA vector, and a PCR-amplified fragment encoding a transmembrane region of human membrane cofactor protein (MCP; nucleotides 953-1203 of MCP cDNA of STBC/CYT2 allotype, a gift from Dr T. Seya, Osaka Medical Center for Cancer and Cardiovascular Diseases, Osaka, Japan), to which XhoI and XbaI sites are attached. A vector pAc-Neo-OVA bearing native OVA cDNA was a gift from Dr T. Sato (Tokai University, Kanagawa, Japan). Expression vectors for I-Ab and  chains were kindly provided by Dr L. Karlsson (R. W. Johnson Pharmaceutical Research Institute, San
Diego, CA). A vector that expresses mouse Pigf cDNA was
reported previously.23
We first stably transfected a Pigf-deficient clone of mouse
thymoma cell line (EL4 Pigf Cell purification Highly purified CD4+ T cells (> 95% pure as assessed by fluorescence-activated cell sorting [FACS]) were prepared from pooled lymph nodes of OTII or bm12 mice by hypotonically lysing erythrocytes, followed by negative selection using the MACS system (cells treated with a cocktail of biotinylated anti-CD8, -HSA, -I-Ab, and -B220 monoclonal antibodies [mAbs],
followed by streptavidin beads; Miltenyi Biotec, Bergish
Gladbach, Germany). Bone marrow cells, flushed from femurs,
were depleted of lineage-marker positive cells by negative selection
using the MACS system (cells treated with a cocktail of anti-CD4, -CD8,
-B220, -Mac-1, and -DX-5 mAbs, followed by streptavidin beads).
In vitro T-cell proliferation Purified CD4+ T cells from OTII or bm12 mice (3 × 105/well) were mixed with various types of EL4 transfectants (5 × 105/well) in flat-bottom 96-well plates in DMEM supplemented with 10% FCS, 2 mM L-glutamine, 5 × 10 5 M 2-mercaptoethanol,
and 100 U/mL penicillin and 100 µg/mL streptomycin. The EL4 cells
were pretreated with 50 µg/mL mitomycin C (Sigma Chemical, St
Louis, MO) for 1 hour and washed 3 times with the medium. For
some experiments, they were pulsed with OVA peptides (5 or 10 µM). Proliferation was assessed on days 4 and 5 by pulsing cultures with [3H]thymidine for 4 hours.
In vivo experimental model of PNH Mice transgenic for hCMV-Cre were generated in the B6 strain according to a previous report.25 Mice with a Piga gene bearing loxP sites within intron 5 and the 3' flanking region (termed Pigaflox) were reported previously.26 The generation of Piga-disrupted hematopoietic stem cells using these 2 mouse strains was also reported.11 Briefly, we crossed Pigaflox males with the hCMV-Cre transgenic females. All female embryos should be heterozygous for Pigaflox and among them those that received the Cre transgene would become heterozygous for Piga disruption and mosaic for Pig-a expression due to random X inactivation. We collected fetal liver cells on 14 days after coitus (dac) as a source of stem cells and transferred them (3 × 106/mouse) intravenously into lethally irradiated B6 hosts (900 cGy irradiation from a 137Cs source). We cotransplanted them with or without purified CD4+ T cells of bm12 mice (7.5 × 104 cells/mouse) together with lineage marker-negative bm12 bone marrow cells (106 cells/mouse) to prevent death from aplasia.27 To distinguish fetal liver-derived cells from other cells, we used mice whose Ly5 allele was 5.1 for the donor of fetal liver and 5.2 for the host and bm12 mice. Flow cytometric analysis of the peripheral blood cells of these chimeric mice was reported previously.11
We tested 2 models to obtain experimental evidence for the
hypothesis that expansion of the GPI
Cells defective in GPI biosynthesis are unable to present antigenic peptides of GPI-anchored proteins on MHC class II molecules To test whether antigenic peptides derived from endogenous GPI-anchored proteins are presented on MHC class II molecules and if so whether the presentation is dependent on GPI anchoring, we used the GPI-anchored form of OVA as a model antigen. We isolated CD4+ T cells from lymph nodes of OTII mice that express transgenic TCR specific for an OVA-derived peptide presented on I-Ab molecules. These T cells were stimulated with GPI+ and GPI EL4 cell lines expressing
I-Ab and various forms of OVA. We first used TM-OVA to
confirm that the GPI EL4 cell line is able to present
peptides derived from OVA on I-Ab molecules. The
GPI EL4 cell line expressing TM-OVA (shaded bar)
stimulated the CD4+ T cells (Figure
2). The efficiency was about one third
that of the GPI+ EL4 cell line expressing TM-OVA (black
bar; 34 000 versus 90 000 cpm; Figure 2). We then tested the
presentation of OVA peptides derived from GPI-OVA. The GPI+
EL4 cell line expressing GPI-OVA stimulated the CD4+ T
cells (black bar), indicating that antigenic peptides derived from
GPI-anchored proteins can be presented on MHC class II molecules. In
contrast, GPI EL4 transfected with the same cDNA encoding
GPI-OVA did not stimulate the CD4+ T cells (shaded bar).
The same GPI EL4 stimulated the CD4+ T cells
when exogenous OVA peptides were added (white bar), confirming that
GPI EL4 had an intact machinery for MHC class
II-dependent antigen presentation. Therefore, cells defective in GPI
anchor biosynthesis are not able to present antigenic peptides of
GPI-anchored proteins on MHC class II molecules.
When GPI anchors are not attached to proteins that are normally GPI
anchored, the proteins are not expressed on the cell surface due either
to degradation in the cytoplasm or to secretion into the extracellular
space.4 Peptides generated in the cytoplasm would not be
presented on MHC class II molecules. To test whether OVA destined for
extracellular secretion is presented on MHC class II molecules, we used
GPI+ and GPI GPI-anchored protein-negative cells are less efficient than GPI-anchored protein-positive cells in MHC class II-mediated stimulation of CD4+ T cells As described above, the GPI EL4 cell line presented
TM-OVA-derived peptide significantly but less efficiently than the
GPI+ counterpart (TM-OVA in Figure 2). FACS analysis showed
that the surface expression of TM-OVA and I-Ab on these 2 cell lines was similar (mean fluorescent channels of GPI+
and GPI cells were 295 and 245 for TM-OVA, and 115 and
145 for I-Ab, respectively.). Considering that a number of
GPI-anchored proteins are involved in cell-to-cell interactions, we
next compared the stimulation of CD4+ T cells in the
presence and absence of GPI-anchored proteins on APCs. To eliminate the
intracellular antigen-processing step, we compared GPI+ and
GPI EL4 cell lines that express I-Ab
molecules but not TM-OVA. These cell lines were pulsed with various concentrations of OVA peptides and then tested for their ability to
stimulate CD4+ T cells from OTII mice. Stimulation of
CD4+ T cells by GPI cells was significantly
weaker than that by the GPI+ counterpart (Figure
3). These results suggest that
GPI-anchored proteins costimulate antigen presentation by
enhancing cell-to-cell interaction and that GPI cells
would be less sensitive to cytotoxic CD4+ T cells.
GPI
gene. CD4+ T cells from bm12 mice are allogeneic to cells
bearing wild-type I-Ab molecules.29 We
compared the proliferative response of bm12 CD4+ T cells to
GPI and GPI+ EL4 cells expressing
I-Ab (shaded and black bars, respectively, in Figure
4). The response of CD4+ T
cells was much weaker to GPI EL4 than GPI+
EL4 cells (2900 versus 8000 cpm in experiment 1 and 3800 versus 17 000
cpm in experiment 2). Therefore, GPI-anchored proteins on stimulator
cells are important for the activation of CD4+ T cells in
the allogeneic response.
GPI
hematopoietic cells to cytotoxic T cells. There is a report that the
transfer of a small number of CD4+ T cells from bm12 mice
to lightly irradiated B6 mice causes lethal pancytopenia due to a
severe graft-versus-host reaction in bone marrow.27 We
transplanted a mixture of GPI+ and GPI fetal
liver cells of B6 background as a source of hematopoietic stem cells
into lethally irradiated B6 mice with or without CD4+ T
cells from bm12 mice as a source of CTLs (Figure
5). To prevent the death of the recipient
mice from aplasia, lineage marker-negative bone marrow cells of bm12
mice were also cotransplanted. The cells derived from fetal liver cells
were Ly5.1+, whereas bm12 mice and recipient mice were
Ly5.2+.
At 5 to 28 weeks after transplantation, we determined percentages of
GPI
In mice that received cotransplantations with CD4+
T cells, percentages of fetal liver-derived cells increased with time
(Figure 6A) in association with a decrease in the percentage of
GPI
This study presents the first experimental evidence that supports
the immunologic selection hypothesis for the clonal expansion of PNH
cells. Especially, it was demonstrated that GPI Second, we demonstrated using in vitro systems that GPI Third, using allogeneic CD4+ T cells in a
transplantation system, we demonstrated the expansion of the
GPI As shown in our mouse system, expansion of the GPI The PNH cells are present in a large proportion of AA
patients.39,40 Although the percentage of
GPI We are not proposing that selection is the only mechanism of clonal
expansion in PNH. The 2 hypotheses (see "Introduction") are not
mutually exclusive and both may be operating. We think that selection
may not be sufficient for high-level expansion of the PIG-A
mutant clone seen in so-called florid PNH. Such a clone may have a
growth phenotype, like benign tumors, owing to additional cytogenetic
abnormalities. Consistent with this idea, there is a recent report that
the early growth response gene (EGR1), a zinc
finger transcription factor, is up-regulated in all cases of PNH
studied.41 When immunologic damage occurs in a pool of hematopoietic stem cells, the surviving GPI The identification of GPI-anchored proteins responsible for the immunologic selection, the demonstration of the target protein that is recognized by autoreactive CTLs in PNH, and the search for additional cytogenetic abnormalities responsible for the growth phenotype are critical to further understand clonal expansion in PNH.
We thank Drs F. R. Carbone, H. Nakauchi, T. Sato, L. Karlsson, T. Seya and T. Kina for their gifts, Dr W. Hazenbos for discussion, Dr Shuichi Yamada for generating transgenic mice, and Keiko Kinoshita and Fumiko Ishii for technical assistance.
Submitted June 6, 2002; accepted July 4, 2002.
Prepublished online as Blood First Edition Paper, July 18, 2002; DOI 10.1182/blood-2002-06-1669.
Supported by grants from the Ministry of Education, Culture, Sports, Science and Technology of Japan.
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: Taroh Kinoshita, Department of Immunoregulation, Research Institute for Microbial Diseases, Osaka University, 3-1 Yamada-oka, Suita, Osaka 565-0871, Japan; e-mail: tkinoshi{at}biken.osaka-u.ac.jp.
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Top
Abstract
Introduction
, EL4 cells defective in GPI anchor biosynthesis; 
,
EL4 cells with normal GPI anchor biosynthesis; and 
,
GPI
indicates control mice (n = 7);
, experimental mice (n = 9). Bars represent mean
percentages.
, which induces MHC class II
expression in various cells,