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Blood, Vol. 92 No. 2 (July 15), 1998:
pp. 353-361
By
From the Division of Bone Marrow Transplantation and Stem Cell
Biology, Department of Medicine and Pathology, Washington University
Medical School, St Louis, MO.
Granulocyte colony-stimulating factor (G-CSF) is the principal
growth factor regulating the production of neutrophils, yet its role in
lineage commitment and terminal differentiation of hematopoietic
progenitor cells is controversial. In this study, we describe a system
to study the role of G-CSF receptor (G-CSFR) signals in granulocytic
differentiation using retroviral transduction of G-CSFR-deficient,
primary hematopoietic progenitor cells. We show that ectopic expression
of wild-type G-CSFR in hematopoietic progenitor cells supports
G-CSF-dependent differentiation of these cells into mature
granulocytes, macrophages, megakaryocytes, and erythroid cells.
Furthermore, we show that two mutant G-CSFR proteins, a truncation
mutant that deletes the carboxy-terminal 96 amino acids and a chimeric
receptor containing the extracellular and transmembrane domains of the
G-CSFR fused to the cytoplasmic domain of the erythropoietin receptor,
are able to support the production of morphologically mature,
chloroacetate esterase-positive, Gr-1/Mac-1-positive neutrophils in
response to G-CSF. These results demonstrate that ectopic expression of
the G-CSFR in hematopoietic progenitor cells allows for multilineage
differentiation and suggest that unique signals generated by the
cytoplasmic domain of the G-CSFR are not required for G-CSF-dependent
granulocytic differentiation.
GRANULOCYTE colony-stimulating factor
(G-CSF) is the principal growth factor regulating the production of
mature neutrophils. In fact, G-CSF is widely used to ameliorate
neutropenia in a variety of clinical settings.1 Multiple
actions of G-CSF have been described that may contribute to the
neutrophilic response. First, G-CSF stimulates the proliferation of
granulocytic precursors.2,3 Second, it reduces the average
transit time through the granulocytic compartment.3-5
Although the effect of G-CSF on neutrophil production is well
established, its role in the commitment of multipotent hematopoietic
progenitors to the myeloid lineage and their subsequent terminal
differentiation into mature neutrophils is controversial.
The biological effects of G-CSF are mediated through its interaction
with the G-CSF receptor (G-CSFR), a member of the cytokine receptor
superfamily.6 To define further the role of G-CSF in the
control of granulopoiesis, we recently generated G-CSFR-deficient mice.7 Similar to G-CSF (cytokine)-deficient
mice,8 G-CSFR-deficient mice have chronic neutropenia with
a uniform decrease in myeloid cells in the bone marrow.7,9
No accumulation of immature granulocytic cells in the bone marrow was
observed, suggesting that the residual granulocytic precursors present
in these mice were able to differentiate normally into mature
neutrophils. In agreement with this conclusion, G-CSFR-deficient
myeloid progenitors demonstrated normal granulocytic differentiation in
vitro in response to interleukin-3 (IL-3) or granulocyte-macrophage
colony-stimulating factor (GM-CSF).7 Surprisingly, near
normal numbers of myeloid-committed progenitors were observed in the
bone marrow of these animals. These data demonstrated that G-CSFR
signals are not required for lineage commitment or terminal
differentiation.
On the other hand, several studies have shown that the addition of
G-CSF to cultures of certain multipotential hematopoietic cell lines
results in their granulocytic differentiation.10-14 Furthermore, a carboxy-terminal region of the cytoplasmic domain of the
G-CSFR was identified that was required for granulocytic differentiation.11-13 These observations lead to the
hypothesis that G-CSFR signals play an active (instructive) role in
directing granulocytic differentiation. This conclusion is compatible
with data from the G-CSFR-deficient mice, because alternative
granulocytic differentiation signals (eg, from other hematopoietic
cytokines) may be able to compensate for the loss of G-CSFR signals in
vivo. In contrast, other studies have shown that granulocytic
differentiation can occur in a cytokine-independent fashion.
Suppression of apoptosis by ectopic expression of bcl-2 allowed for
granulocytic differentiation of hematopoietic cell lines in the absence
of added cytokines (although certain features of granulocytic
differentiation seemed to require G-CSF).15,16 These
conflicting data highlight the controversy as to the presence and
contribution of specific G-CSFR signals to granulocytic
differentiation.
In this study, we describe a system to study the role of G-CSFR signals
in the granulocytic differentiation of primary hematopoietic progenitor
cells that lack endogenous G-CSFR protein. In addition to wild-type
G-CSFR, two mutant G-CSFR were studied: a truncation mutant that
deletes the carboxy-terminal 96 amino acids (including the putative
maturation domain) and a chimeric receptor containing the extracellular
and transmembrane domains of the G-CSFR fused to the cytoplasmic domain
of the erythropoietin receptor. The effect of ectopic expression of
these receptors on G-CSF-dependent hematopoietic proliferation and
differentiation was assessed.
Cytokines, cell lines, and mice.
Human flt-3 ligand and murine kit ligand were generously provided by
Immunex (Seattle, WA). Human thrombopoietin was a generous gift from Dr
John DiPersio (Washington University, St Louis, MO). The amphotropic
and ecotropic packaging cell lines GP+EnvAm12 and GP+E86,17
respectively, were maintained in Dulbecco's modified Eagle's medium
(DMEM) supplemented with 10% heat-inactivated fetal calf serum (FCS),
15 µg/mL of hypoxanthine, 250 µg/mL of xanthine, and 25 µg/mL of
mycophenolic acid (HXM media) at 37°C in a 5% CO2,
humidified atmosphere. The generation of G-CSFR-deficient mice has
been described previously.7 All mice were housed in a
specific pathogen-free environment.
Construction of G-CSFR retroviral plasmids.
The wild-type and mutant G-CSFR cDNAs were subcloned into the
retroviral vector pMPncrdlneo.18 The d716 G-CSFR mutation was generated using a polymerase chain reaction (PCR)-based method to
introduce a C to T mutation at nucleotide 2403, as
described.19 The murine G-CSFR cDNA was used as the
template in PCR reactions with the following oligonucleotide primer
pairs: exon 16 forward primer (5 Retroviral infection of bone marrow cells.
The retroviral constructs were linearized with Sac-2, transfected into
GP+EnvAm12 cells using lipofectamine (GIBCO BRL, Gaithersburg, MD), per
the manufacturer's recommendations, and selected in HXM media
supplemented with 800 µg/mL geneticin (GIBCO BRL). The amphotropic retrovirus-rich supernatant from geneticin-resistant cells was used to
infect GP+E86 cells. Individual geneticin-resistant GP+E86 clones were
derived, and their supernatant was tested for viral production on
NIH3T3 cells. Clones producing 0.5 to 1.0 × 106
infectious particles/mL were obtained for each construct.
Flow cytometry.
To assess surface G-CSFR expression, nonadherent cells from the
cultures described above were incubated at 4°C for 1 hour with
biotinylated G-CSF (generated as described7; 5 ng per
106 cells) in the presence or absence of a 100-fold molar
excess of nonlabeled G-CSF, followed by incubation with phycoerythrin (PE)-conjugated streptavidin (GIBCO BRL). Cells were coincubated with
the following cocktail of lineage-restricted fluorescien isothiocyanate
(FITC)-conjugated rat monoclonal antibodies: antimouse B220 (M1/70,
IgG2b), antimouse CD3 (M1/70, IgG2b), and
antimouse CD11b (M1/70, IgG2b). In other experiments,
PE-conjugated rat antimouse CD11b (M1/70, IgG2b; PharMingen, San Diego,
CA) and FITC-conjugated rat antimouse Gr-1 (RB6-8C5, IgG2b) were used. In all experiments, cells were incubated with actinomycin D, 7-amino (7AAD) to exclude nonviable (7AAD-positive) cells from analysis. All
antibodies were purchased from PharMingen. All cells were analyzed
using a FACScan flow cytometer and CellQuest version 1.2.2 software
(Becton Dickinson, Mansfield, MA).
Cell sorting.
Nonadherent cells from the cultures described above were incubated with
biotin-conjugated rat antimouse CD34 (RAM34, IgG2a) and the
same cocktail of FITC-conjugated lineage-restricted antibodies as
described above. After incubation with PE-conjugated streptavidin, CD34+ lineage Progenitor assays.
Seven hundred fifty to 2,000 CD34+
lineage Cytological analysis.
Entire methylcellulose cultures were harvested on day 10 and leukocyte
differentials were performed on Wright-stained cytospin preparations.
Acetylcholine esterase20 and 2,7-diaminofluorene (DAF)21 stains were performed as described. For flow
cytometry, cells were washed extensively and incubated with Fc block
(PharMingen) per the manufacturer's recommendations before incubating
with the indicated antisera.
Statistical analysis.
Data represent the mean ± SD. Statistical significance was assessed
by the Student's t-test.
High efficiency transduction of G-CSFR-deficient hematopoietic cells
with G-CSFR-expressing retrovirus.
Most current models of granulocytic differentiation use immortalized
cell lines; however, these models are often limited by incomplete
differentiation and inappropriate gene expression. A system was
developed to study the effect of wild-type (or mutant) G-CSFR
expression on the granulocytic differentiation of primary hematopoietic
cells using retroviral transduction. Hematopoietic cells isolated from
G-CSFR-deficient mice were used in these studies because they lack
endogenous G-CSFR. In initial experiments, the ability of three
different G-CSFR proteins to support hematopoietic proliferation and
differentiation were examined (Fig 1). In
addition to wild-type murine G-CSFR (WT), two mutant receptors were
studied. The d716 mutation truncates the distal 96 amino acids of the
carboxy-terminal tail and reproduces a mutation of the G-CSFR found in
a patient with severe congenital neutropenia.22 Expression
of a similarly truncated G-CSFR in a myeloid cell line blocked
G-CSF-dependent granulocytic differentiation.22 The GEpoR
mutation produces a chimeric receptor with the extracellular
(ligand-binding), transmembrane, and the first four amino-acids of the
cytoplasmic domain derived from the G-CSFR and the remaining
cytoplasmic domain derived from the murine erythropoietin receptor. The
first four amino acids of the cytoplasmic domain of the G-CSFR were
retained solely to facilitate the subcloning of the GEpoR construct.
This chimeric receptor is predicted to transmit erythropoietin-specific
signals in a G-CSF-dependent fashion.
All three G-CSFR proteins support G-CSF-dependent hematopoietic
colony formation.
Hematopoietic cells transduced with WT, d716, GEpoR, or control (neo)
retrovirus produced similar numbers of colonies in response to the
cytokines present in pokeweed mitogen-stimulated spleen conditioned
media (Fig 3A). No colonies were detected
in any culture without added cytokine (Fig 3B). As expected, the
neo-transduced cells did not produce any colonies in response to G-CSF
even at the highest concentration (100 ng/mL). Cells transduced with
the WT, d716, or GEpoR constructs produced similar number of colonies in response to G-CSF at concentrations of 10 or 100 ng/mL.
Interestingly, at the lowest concentration of G-CSF (1 ng/mL),
significant differences were detected in the frequency of colony
formation. Compared with wild-type transduced cells, significantly
fewer colonies were detected in cultures of GEpoR-transduced cells; in
contrast, significantly greater numbers of colonies were detected in
cultures of d716-transduced cells. A nonsignificant trend to increased
colony size was observed with GEpoR-transduced cells compared with WT-
or d716-transduced cells; on day 10 of G-CSF stimulation (100 ng/mL),
the mean number of cells per colony ± SD was as follows: WT, 1,504 ± 322; d716, 2,068 ± 693; and GepoR, 3,098 ± 1,403.
All three G-CSFR proteins support a similar degree of granulocytic
differentiation.
Hematopoietic colonies stimulated by G-CSF were harvested on day 10 of
culture and their cellular composition was analyzed. In cultures of
WT-, d716-, or GEpoR-transduced cells the predominant cell types
observed in the G-CSF-stimulated colonies were macrophages and cells
of the granulocytic lineage (Fig 4A
through C and Table 1). In fact, a similar number of
mature-appearing neutrophils were observed in each of these cultures.
The only consistent difference observed in these experiments was a
delay in granulocytic differentiation of GEpoR transduced cells; after
7 days of G-CSF stimulation, a greater fraction of cells were immature
granulocytic precursors (data not shown). To confirm the presence of
myeloid cells, the expression of Mac-1 and Gr-1 (proteins that are
expressed predominantly on myeloid cells) was examined by flow
cytometry (Fig 5). The majority of cells in
cultures of WT-, d716-, or GEpoR-transduced cells stained brightly for
Mac-1 and Gr-1, a pattern consistent with mature neutrophils and late
granulocytic precursors.23 Another characteristic of mature
neutrophils is the presence of chloroacetate esterase.24
Although the intensity of staining was reduced relative to normal
murine neutrophils, the majority of granulocytic cells in each of these
cultures clearly stained positive for chloroacetate esterase (Fig 4D
through F). Collectively, these data indicate that all three G-CSFR
proteins are able to support a similar degree of granulocytic
differentiation.
Ectopic expression of the G-CSFR in hematopoietic progenitor cells
allows for G-CSF-dependent multilineage differentiation.
In G-CSF-stimulated cultures of WT-, d716-, or GEpoR-transduced cells,
a small number of granulocyte-erythrocyte-macrophage-megakaryocyte colony-forming unit (CFU-GEMM) and burst-forming unit-erythroid (BFU-E) colonies were observed (data not shown). In
agreement with this observation, erythroid cells and megakaryocytes
were consistently detected in these cultures (Table 1 and data not shown). The presence of megakaryocytes was confirmed by the detection of acetylcholine esterase-positive multinucleated cells (data not
shown). Likewise, the presence of erythroid cells was confirmed by the
demonstration of DAF-positive (hemoglobinized) cells (data not shown).
Either the autocrine production of growth factors by the hematopoietic
cells or the trace amounts of growth factors present in fetal calf
could contribute to the multilineage differentiation observed. We
therefore investigated whether neutralizing antibodies to
erythropoietin and thrombopoietin could block erythroid or megakaryocytic differentiation in G-CSF-stimulated cultures. After 10 days of culture, a similar number of erythroid and megakaryocytic cells
were observed (data not shown). Collectively, these data indicate that
the G-CSFR is able to generate signals in progenitor cells that support
the production of mature granulocytes, macrophages, megakaryocytes, and
erythroid cells.
Hematopoietic cytokines clearly play an important role in the
regulation of hematopoiesis, yet the mechanisms by which they exert
their control are unclear. In this study, we describe a system to study
the role of G-CSFR signals in granulocytic differentiation using
retroviral transduction of G-CSFR-deficient, primary hematopoietic progenitor cells. This approach has several advantages over the use of
immortalized myeloid cell lines to study granulocytic differentiation. First, the target cell population is comprised of primary progenitor cells (not cells that have been adapted to long-term culture). Second,
the target cells completely lack endogenous G-CSFR. Using this system,
we show that ectopic expression of wild-type G-CSFR in hematopoietic
progenitor cells supports G-CSF-dependent differentiation of these
cells into mature granulocytes and macrophages. Furthermore, we show
that two mutant G-CSFR proteins, d716 (a truncation mutant that deletes
the carboxy-terminal 96 amino acids) and GEpoR (a chimeric receptor
containing the extracellular and transmembrane domains of the G-CSFR
fused to the cytoplasmic domain of the erythropoietin receptor), also
are able to support the production of morphologically mature,
chloroacetate esterase-positive, Gr-1/Mac-1-positive neutrophils in
response to G-CSF. Surprisingly, along with granulocytes and macrophages, these G-CSFR proteins also were able to support the production of mature megakaryocytes and erythroid cells.
Submitted March 19, 1998;
accepted April 21, 1998.
The authors thank Dr Mark Sands for his assistance in the generation of
high-titer retrovirus. We also thank Jennifer Poursine-Laurent for her
expert technical assistance.
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|
Abstract
Introduction
Abstract
-CCCACAGTAGCCTGAGCTCC-3
-minimum essential medium (
cells were sorted using a
Coulter Elite ESP cytometer (Coulter, Hialeah, FL).
-common chain of the GM-CSF receptor may contribute to
GM-CSF-dependent macrophage differentiation in a cell-specific manner.
Their data suggested that both the strength of the differentiative
signal and the pool of available signaling intermediates determined the differentiation response. It is therefore possible that the high level
of receptor expression achieved with retroviral promoters may allow for
an otherwise weak (and possibly nonphysiological) signal to initiate a
differentiation program. For example, multiple regions of the G-CSFR
may normally be required to induce granulocytic differentiation; the
loss of one region (ie, membrane-distal region) may be compensated for
by the overexpression of the remaining receptor regions. A confirmation
of our findings in mice carrying a similar targeted G-CSFR mutation in
which the level of GEpoR expression is physiological and
lineage-restricted is therefore warranted.
