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Blood, Vol. 95 No. 8 (April 15), 2000:
pp. 2569-2576
HEMATOPOIESIS
From the Department of Experimental Anaesthesiology, University
Hospital Freiburg, Center for Tumor Biology, Freiburg, Germany; the
Department of Hematology and Oncology, University Hospital Freiburg,
Freiburg, Germany; the Center for Tumor Biology, Freiburg, Germany; the
Department of Hematology/Oncology, University Hospital Munich, Munich,
Germany; and the Department of Pathology, University Hospital Freiburg,
Freiburg, Germany.
Polycythemia vera (PV) is a clonal stem cell disorder characterized
by hyperproliferation of the erythroid, myeloid, and megakaryocytic lineages. Although it has been shown that progenitor cells of patients
with PV are hypersensitive to several growth factors, the molecular
pathogenesis of this disease remains unknown. To investigate the
molecular defects underlying PV, we used subtractive hybridization to
isolate complementary DNAs (cDNAs) differentially expressed in patients
with PV versus normal controls. We isolated a novel gene, subsequently
named PRV-1, which is highly expressed in granulocytes from patients
with PV (n = 19), but not detectable in normal control granulocytes
(n = 21). Moreover, PRV-1 is not expressed in mononuclear cells from
patients with chronic myelogenous leukemia (n = 4) or acute
myelogenous leukemia (n = 5) or in granulocytes from patients with
essential thrombocythemia (n = 4) or secondary erythrocytosis
(n = 4). Northern blot analysis showed that PRV-1 is highly expressed
in normal human bone marrow and to a much lesser degree in fetal liver.
It is not expressed in a variety of other tissues tested. Although
PRV-1 is not expressed in resting granulocytes from normal controls,
stimulation of these cells with granulocyte
colony-stimulating factor induces PRV-1 expression. The PRV-1 cDNA
encodes an open reading frame of 437 amino acids, which contains a
signal peptide at the N-terminus and a hydrophobic segment at the
C-terminus. In addition, PRV-1 contains 2 cysteine-rich domains
homologous to those found in the uPAR/Ly6/CD59/snake
toxin-receptor superfamily. We therefore propose that PRV-1
represents a novel hematopoietic receptor.
(Blood. 2000;95:2569-2576)
Polycythemia vera (PV) is 1 of 4 diseases termed the
myeloproliferative disorders (MPDs).1 Besides PV, this
group includes essential thrombocythemia (ET), idiopathic myelofibrosis
(IMF), and chronic myelogenous leukemia (CML). All MPDs result from the clonal expansion of a mutant pluripotent hematopoietic stem
cell.2-5 PV is characterized by an increased proliferation
of all 3 myeloid lineages, which results in an excess production of
mature red cells, granulocytes, and platelets.6 Because the
disease results from the hyperproliferation of a single aberrant stem
cell, the peripheral red blood cells, granulocytes, monocytes, and
platelets are clonal in these patients.2,7-9 Although the
molecular etiology of PV remains unknown, progress has recently been
made in characterizing the malignant cells.
The PV cells are hypersensitive to several hematopoietic growth factors
including interleukin-3 (IL-3), granulocyte/macrophage colony-stimulating factor (GM-CSF), stem cell factor (SCF), and thrombopoietin (TPO).10-13 However, regarding
erythropoietin (EPO), a long debate had ensued whether PV cells are
hypersensitive to or in fact independent of this growth factor. In
elegant experiments using a novel serum-free medium devoid of any
burst-promoting activity, Correa et al have recently shown that PV
erythroid progenitor cells are independent of EPO.14 In
addition, these cells are exquisitely hypersensitive to insulin-like
growth factor-1 (IGF-1).14 Interestingly, patients with PV
also show 4-fold elevated plasma levels of insulin-like growth factor
binding protein-1 (IGFBP-1), which, together with IGF-1, stimulates
erythroid burst formation in vitro.15
The observation that PV cells are hypersensitive to a large variety of
growth factors suggests that signal transduction pathways may be
altered in these cells. Moliterno and colleagues have recently reported
that platelets from patients with PV displayed impaired tyrosine
phosphorylation in response to TPO stimulation, whereas the response to
thrombin remained intact.16 The TPO response was also
deficient in patients with IMF, but not in patients with a variety of
other hematopoietic diseases. The inability to transduce the TPO signal
was due to a dramatic reduction or a complete absence of the TPO
receptor, c-mpl, in 34 of 34 PV and 13 of 14 IMF
patients.16 However, it is at present not clear how a loss
of c-mpl expression could contribute either to the growth factor
hypersensitivity of PV cells, or, more generally, to the molecular
pathology of the disease.
An intriguing observation about PV cells was recently reported. Silva
et al showed that PV erythroid precursor cells express the
anti-apoptotic protein bcl-xL to a much higher
proportion than normal precursor cells (21.8% versus
6.6%).17 In addition, in PV, more mature cells, which
normally show no bcl-xL expression, still
express high levels of the protein. Hematopoietic growth factors act in
part by suppressing apoptosis. IGF-1, in particular, has been shown to
suppress apoptosis of erythroid progenitors and myeloid
cells.18,19 Thus, perhaps the observed growth factor hypersensitivity of PV cells results from an intrinsic protection from
apoptosis, thereby requiring less protection through growth factor stimulation.
Despite these recent advances in characterizing the malignant PV clone,
the molecular defect leading to the development of this disease remains
unclear. In an attempt to find such a defect, we wished to define
differences in gene expression between PV and normal cells. We used
subtractive hybridization to clone complementary DNAs (cDNAs) that are
either over- or underexpressed in PV cells. We report here the cloning
of a novel hematopoietic cell surface receptor, which is strongly
overexpressed in cells from 19 of 19 patients with PV and not expressed
in 21 of 21 normal controls. We have named this novel receptor
polycythemia rubra vera-1 (PRV-1).
Patients
Separation of cells
RNA isolation and Northern blots
Isolation of poly(A)+RNA and subtractive hybridization Poly(A)+RNA was isolated using the Fast Track 2.0 Kit (Invitrogen, Carlsbad, CA). Double-stranded cDNA was synthesized using the PCR-Select cDNA Subtraction Kit (Clontech) at the manufacturer's recommendation. Subtractive hybridization was performed with cDNA from PV granulocytes pooled from 5 patients (MT, WZ, IP, FB, and DJ, Table 1) and cDNA from normal control granulocytes using the PCR-Select cDNA Subtraction Kit (Clontech) according to the manufacturer's recommendation. The subtracted cDNA was cloned directly into the pCR 2.1 vector (TA Cloning Kit, Invitrogen).Western blots Total cell extracts were prepared using a high-salt detergent buffer (Totex) as previously described.22 Cell extracts (30 µg) were boiled in Laemmli sample buffer and subjected to SDS-polyacrylamide gel electrophoresis (PAGE) and Western blotting as described.22 Primary polyclonal antibodies were raised by injection of 2 hapten coupled synthetic peptides into rabbits. These peptides encode amino acids 13 to 25 and 368 to 383 of the predicted mature PRV-1. The purified rabbit serum was used at a dilution of 1:500. Bound antibody was decorated with peroxidase conjugated secondary antibody (goat antirabbit IgG, Amersham). The immunocomplexes were detected using ECL Western blotting reagents (Amersham). Exposure to Kodak XAR-5 films was performed for 5 to 10 seconds.Immunohistochemistry The bone marrow biopsy was decalcified, paraffin embedded, and stained as previously described.23-25 Serial sections were stained as follows: (1) with a mouse polyclonal antiserum raised against native PRV-1 by DNA vaccination (Genovac GmbH, Freiburg, Germany); for vaccination, the 1.4-kb PRV-1 coding region cloned into pCDNA3.1 (Invitrogen) was used; (2) enzymatically for naphthol-AS-D-chloroacetate esterase; or (3) with an antibody against hemoglobin (DAKO, Hamburg, Germany).
Cloning of PRV-1 Messenger RNA (mRNA) from granulocytes of 5 PV patients (MT, WZ, IP, FB, and DJ, Table 1) was compared to normal granulocyte mRNA in a subtractive hybridization. Five clones were obtained, which encoded different overlapping fragments of the same cDNA. Northern blot hybridization to granulocyte RNA from 5 patients with PV and 5 healthy volunteers showed that this cDNA hybridized to 2 distinct RNAs, 2.1 kb and 3.1 kb in size, in all 5 PV patients, but showed no hybridization to normal granulocyte RNA (Figure 1). RNA from a total of 19 patients with PV and 21 normal controls has been analyzed to date. In Northern blots, peripheral blood granulocytes from all 19 PV patients displayed strong hybridization to the cDNA probe, whereas none of the controls showed a detectable signal (data not shown).
Structure of the PRV-1 protein From 3 clones, a complete cDNA was constructed. (The nucleotide sequence has been submitted to the GenBank/EBI Data Bank with the accession number AF 146747.) Homology searches with several databases revealed that the sequence represents a novel previously uncharacterized cDNA, which we subsequently named polycythemia rubra vera-1 (PRV-1). This sequence encodes an open reading frame of 437 amino acids (Figure 2), which contains the following features: (1) an N-terminal signal sequence of 21 amino acids, (2) 2 highly homologous cysteine-rich domains of 188 amino acids, and (3) a highly hydrophobic C-terminal sequence.
PRV-1 expression in MPDs
PRV-1 expression in normal tissues
PRV-1 expression in bone marrow
PRV-1 expression is stimulated by granulocyte colony-stimulating
factor and GM-CSF
We describe the cloning of a novel cell surface receptor,
named PRV-1 (polycythemia rubra vera-1), which under physiologic conditions is selectively expressed in human bone marrow. The amino
acid sequence of PRV-1 shows that it is a novel protein most closely
related to members of the uPAR/Ly6/CD59 family of cell surface
receptors. Overall amino acid identity between members of this family
is low, ranging between 20% and 30%.30 However, the
family is defined by the presence of cysteine-rich domains, which
contain 8 to 10 cysteine residues spaced at conserved
distances.28 PRV-1 contains 2 cysteine-rich domains that
are highly homologous to each other, showing 42% identity over 146 amino acids (Figure 2). In each of these domains, 6 cysteines are
spaced precisely like those found in the uPAR domains (Figure 3). At
first sight, the remaining cysteines found in the classical uPAR domain
appear to be missing. However, all uPAR domains described
to date contain a "signature sequence," a conserved
sequence found around the last 2 C-terminal cysteine residues of the
domain (cysteines 7 and 8, or 9 and 10, depending on the number of
cysteines in the domain).26,32 This signature sequence
consists of 7 residues with the sequence CXXDXCN. This sequence is also
found twice in PRV-1 (amino acids 104-111 and amino acids 294-300;
amino acids 104-111 contain 1 additional amino acid resulting in the
sequence CXXXDXCN). However, instead of occurring at the C-terminus of the cysteine-rich domain, where this sequence is found in all other
uPAR/Ly6/CD59 family members, in PRV-1 it is found N-terminal to the
other cysteines.
The authors would like to thank Brigitte Schneider
and Gesa Santos for excellent technical assistance. We gratefully
acknowledge very helpful and stimulating discussions with Prof Dr J. Prchal and Dr F. Schriever. Our sincere thanks go to Prof Dr K. Geiger for his continuing support. A very special thank you to the
helpful staff of the hematology clinic and the therapy ward. Thanks
also to the Photo Center at the University Hospital Freiburg for
excellent photographic support. This article is dedicated to Irmgard
Pahl, mother of the senior author; her diagnosis with polycythemia vera sparked this research.
Submitted May 4, 1999; accepted December 17, 1999.
Reprints: Heike L. Pahl, Department of Experimental
Anaesthesiology, University Hospital Freiburg, Center for Tumor Biology, PO Box 1120, 79106 Freiburg, Germany; e-mail:
pahl{at}uni-freiburg.de.
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.
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Top
Abstract
Introduction
-32P-dCTP (Amersham,
Uppsala, Sweden). The blots were washed 3 times for 10 minutes in
2× sodium chloride sodium citrate (SSC), 0.05% sodium dodecyl
sulfate (SDS) at room temperature and twice at 50°C for 20 minutes
in 0.1 × SSC, 0.1% SDS.
-actin cDNA.
-sites, potential sites of GPI-anchor attachment, are shown. The
postulated cysteine-disulfide bridges are indicated by brackets.
B.
J Exp Med.
1996;183:1829