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Blood, Vol. 91 No. 8 (April 15), 1998:
pp. 2664-2671
An In Vitro Model of Human Red Blood Cell Production From
Hematopoietic Progenitor Cells
By
Punam Malik,
Timothy C. Fisher,
Lora L.W. Barsky,
Licheng Zeng,
Parvin Izadi,
Alan L. Hiti,
Kenneth I. Weinberg,
Thomas D. Coates,
Herbert J. Meiselman, and
Donald B. Kohn
From the Divisions of Research Immunology/Bone Marrow Transplantation
and Hematology-Oncology, Childrens Hospital Los Angeles, Los Angeles,
CA; and the Departments of Physiology and Biophysics and of Pathology,
University of Southern California School of Medicine, Los Angeles, CA.
 |
ABSTRACT |
Hemoglobinopathies, such as  -thalassemias and sickle cell anemia
(SCA), are among the most common inherited gene defects. Novel models of human erythropoiesis that result in terminally differentiated red blood cells (RBCs) would be able to address the
pathophysiological abnormalities in erythrocytes in congenital RBC
disorders and to test the potential of reversing these problems by gene
therapy. We have developed an in vitro model of production of human
RBCs from normal CD34+ hematopoietic progenitor cells,
using recombinant growth factors to promote terminal RBC
differentiation. Enucleated RBCs were then isolated to a pure
population by flow cytometry in sufficient numbers for physiological
studies. Morphologically, the RBCs derived in vitro ranged from early
polylobulated forms, resembling normal reticulocytes to smooth
biconcave discocytes. The hemoglobin pattern in the in vitro-derived
RBCs mimicked the in vivo adult or postnatal pattern of -globin
production, with negligible  -globin synthesis. To test the gene
therapy potential using this model, CD34+ cells were
genetically marked with a retroviral vector carrying a cell-surface
reporter. Gene transfer into CD34+ cells followed by
erythroid differentiation resulted in expression of the marker gene on
the surface of the enucleated RBC progeny. This model of human
erythropoiesis will allow studies on pathophysiology of congenital RBC
disorders and test effective therapeutic strategies.
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INTRODUCTION |
MOLECULAR DEFECTS that cause sickle cell
anemia (SCA) and the other common hemoglobinopathies have been well
characterized.1-5 Genetic correction of hematopoietic stem
cells with adequate expression of the inserted gene product in the
defective red blood cells (RBCs; gene therapy) could revolutionize
treatment of congenital RBC defects. Novel models of human
erythropoiesis that result in terminally differentiated RBCs would be
able to address the pathophysiological abnormalities in erythrocytes in
congenital RBC diseases and to test the potential of reversing these
problems by gene therapy.
The most commonly available in vitro assays of erythropoiesis from
CD34+ progenitor cells are based on semi-solid medium
colony-forming assays, which result in colonies consisting of nucleated
erythroid cells. These erythroid colonies are either the early erythoid progenitors (burst- and colony-forming unit-erythroid [BFU-E]) or the
late erythroid progenitors (colony-forming unit-erythroid [CFU-E]).6,7 Most of the in vitro liquid cultures from
CD34+ progenitor cells are limited by the production of
heterogeneous mixtures of mainly myeloid cells with few erythroid
cells. Terminal erythroid differentiation has been reported when
peripheral blood mononuclear cells are initially cultured in semi-solid
media containing different growth factors for about 1 week, and then
the cells (enriched in erythroid precursors) are transferred to a
liquid culture containing erythropoietin (Epo) and grown under reduced oxygen concentrations.8-10 However, generation and
isolation of terminally differentiated enucleated RBCs from highly
purified human CD34+ progenitor cells in a single-step
liquid culture system in vitro has not been previously described.
In this study, we report an in vitro model for production of human
erythrocytes from purified human CD34+ progenitor cells in
liquid culture followed by isolation of the enucleated erythrocytes by
flow cytometry. Erythrocytes generated in this model showed an adult
pattern of -globin production. Gene transfer into CD34+
cells followed by erythroid differentiation resulted in expression of
the marker gene on the surface of the enucleated RBC progeny.
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MATERIALS AND METHODS |
Isolation of CD34+ cells and culture conditions.
CD34+ progenitor cells were obtained from normal human bone
marrow aspirates, from umbilical cord blood collected after normal deliveries, or from peripheral blood cells or bone marrow from patients
with homozygous sickle cell disease. Use of all samples was approved by
the Committee on Clinical Investigations at Childrens Hospital Los
Angeles (Los Angeles, CA). Light-density mononuclear cells were
obtained by centrifugation on ficoll-hypaque (Pharmacia, Piscataway,
NJ), as previously described.11,12 The accompanying RBCs
were lysed by suspending the mononuclear cell pellet in Ortholysis buffer (Ortho Diagnostic Systems, Inc, Raritan, NJ). The mononuclear cells were then enriched for CD34+ cells by two cycles of
positive selection using anti-CD34 antibody and immunomagnetic beads
(typically to >90% to 95% purity) using Mini-MACS columns (Miltenyi
Biotech, Auburn, CA). CD34+ cells were then cultured at a
density of 105 cells/mL in Iscove's Modified Dulbecco's
Medium (IMDM; GIBCO, Grand Island, NY), 1% deionized bovine serum
albumin (BSA; Sigma, St Louis, MO), 10 4 mol/L
2-mercaptoethanol, 106 mol/L hydrocortisone, 100 U/mL penicillin-streptomycin, and 2 mmol/L
L-glutamine with the following recombinant
cytokines: 10 U/mL of recombinant human (rH) Epo (Amgen,
Thousand Oaks, CA), 0.001 ng/mL rH granulocyte-macrophage
colony-stimulating factor (GM-CSF), and 0.01 U/mL rH interleukin-3
(IL-3; Immunex Corp, Seattle, WA) and incubated in 5% CO2
at 37°C.
Antibody labeling and flow cytometry.
Erythroid cultures were harvested after 3 weeks. The cells were washed
in phosphate-buffered saline (PBS) and resuspended in Hoechst buffer
(IMDM containing 1% fetal calf serum [FCS] and 10 µg/mL of Hoechst
33342 [Sigma]) at a concentration of 106 cells/mL and
incubated at 37°C for 90 minutes, shielded from light. The cells
which were negative for fluorescence with the Hoechst dye were sorted
using a dual argon/UV laser on a FACS Vantage flow-cytometer (Becton
Dickinson, San Jose, CA). The Hoechst dye was excited with the 351 to
364 nm UV laser set to 50 mW and its fluorescence was measured using a
450/20 nm band pass filter (Omega Optical Inc, Brattleboro, VT). A
505-nm short pass dichroic mirror was used to separate emission
wavelengths.13
For concomitant staining for surface markers, cells stained with
Hoechst 33342 were pelleted, suspended at a concentration of
106 cells/100 µL Hoechst buffer at 4°C, and incubated
with 6 µL of human Ig (10 mg/mL; Sandoz, East Hanover,
NJ) for 20 minutes to block nonspecific antibody binding.
Cells were then incubated for 20 minutes with 15 µL of biotin-labeled
antibody to rat tNGFR, MC192 (0.1 µg/mL; Oncogene Science, Uniondale,
NY) and then washed twice with PBS to remove excess antibody. Cells
were then stained with 5 µL of phycoerythrin (PE)-labeled strepavidin
(Caltag, San Francisco, CA) for 20 minutes, washed twice in PBS to
remove excess secondary antibody, resuspended in Hoechst buffer, and
stained with fluorescein isothiocyanate (FITC)-conjugated antihuman
glycophorin A antibody (Immunotech, Marseille, France) for an
additional 20 minutes. After 20 minutes of incubation, cells were
washed to remove excess antiglycophorin antibody and resuspended in the Hoechst buffer before flow cytometry. FITC and PE emissions were measured using standard 530/30 and 575/26 dichroic filters. The presence or absence of Hoechst fluorescence was used to separate enucleated erythrocytes from the nucleated erythroid cells in the
culture.
RBC volume determinations.
Mean cell volumes and volume distribution were determined using an
aperture-impedence cell-sizing device, the Coulter counter (Coulter,
Miami, FL).
High-performance liquid chromatography (HPLC) analyses
of globin chains.
The types of globin chains produced in the erythrocytes derived in
vitro from CD34+ cells and control blood samples were
resolved by reverse-phase HPLC on a 4.6 × 250 mm large pore
C4 column (Vydac Separations Group, Inc, Hisperia, CA) with
a 44% to 56.5% linear gradient between mixtures of 0.1% aqueous
trifluoroacetic acid and 0.1% trifluoroacetic acid in acetonitrile at
a flow rate of 1 mL/min on a Beckman system Gold with Solvent module
125 and Detector module 166 set at 220 nm (Beckman Instrument, Inc,
Fullerton, CA). Hemolysates were made by lysing
106 erythrocytes/sample in 10 µL of HPLC grade water for
10 minutes. The hemolysate was mixed with 40 µL of aqueous
acetonitrile and centrifuged at 70,000g for 3 minutes to remove
membranes. Twenty microliters of the hemolysate containing
approximately 1 µg of hemoglobin was used for each run. The same
number of umbilical cord blood RBCs and adult peripheral blood RBCs
were used as controls.
Construction and packaging of the retroviral vectors.
The truncated rat nerve growth factor receptor (tNGFR) cDNA was used as
a cell surface reporter gene in a Moloney murine leukemia retroviral
vector backbone. Details of truncation of the rat NGFR cDNA have been
described previously.14 A Pvu II-EcoRI
fragment of the tNGFR cDNA was cloned into the Xba
I-EcoRI sites of the LXSN vector backbone.15 The
construct was transfected into PA317 cells and viral supernatant from
L-tNGFR-SN PA317 cells was used to infect PG13 producer cells (obtained
from American Type Culture Collection [ATCC], Rockville,
MD),16 as previously described.14 All producer
cells were cultured in Dulbecco's modified Eagle's medium (DMEM;
GIBCO) with 10% FCS. A high-titer clone of L-tNGFR-SN PG13 cells
(clone 9), with a viral titer of 1 to 2 × 106
infectious units/mL, was derived by limiting dilutions and FACS analyses.14 Viral supernatants from the L-tNGFR-SN (clone
9) were harvested after 48 hours of culture of confluent monolayers in
DMEM with 10% FCS at 32°C, were filtered through 0.45-µm
filters, and were used for CD34+ cell transductions.
Transduction of CD34+ cells.
CD34+ cells were suspended at a density of 105
cells/mL in basal bone marrow medium (BBMM; IMDM with 30% FCS, 1% BSA
[Sigma], 104 mol/L 2-mercaptoethanol,
106 mol/L hydrocortisone, 100 U/mL penicillin, 100 µg/mL streptomycin, 2 mmol/L L-glutamine)
containing the following cytokines: 10 U/mL of rH Epo, 0.001 ng/mL rH
GM-CSF, and 0.01 U/mL rH IL-3. CD34+ cells were plated on
dishes coated either with irradiated normal human bone marrow stromal
cell monolayers11 or with the CH-296 fragment of
recombinant fibronectin (supplied by Takara Shuzo, Otsu, Japan), as
recommended by the manufacturer's protocol. Half the culture media was
replaced twice daily, 12 hours apart, with filtered viral supernatant
from the L-tNGFR-SN PG13 cells for 3 days. On days 4 and 5, cells were
harvested, labeled with the antibody to NGFR (MC192) as described
above, and sorted on the FACS-Vantage flow cytometer.
| |
RESULTS |
In vitro model for production of RBCs from human CD34+
progenitor cells.
CD34+ cells were isolated from the mononuclear cell
fraction from cord blood, bone marrow, or peripheral blood to greater
than 90% to 95% purity. The mononuclear fraction was subjected to RBC lysis before CD34 isolation to prevent any previously formed RBCs from
contaminating the cultures. The purified human CD34+ cells
were placed in erythroid differentiation conditions by using very high
concentrations of Epo and low concentrations of GM-CSF and IL-3 in
liquid culture, as detailed in the Materials and Methods.
Differentiation was assessed by Wright Giemsa staining of portions of
the cultured cells at serial time intervals to determine morphology.
Figure 1 shows a representative experiment
performed using bone marrow CD34+ cells cultured in
erythroid differentiation conditions. Nearly all of the cells in
culture consisted of erythroid cells that serially recapitulated in
vivo erythropoiesis. Most of the cells in the culture consisted of
pronormoblasts at day 7 (Fig 1A), basophilic normoblasts by 9 to 10 days (Fig 1B), and polychromatophilic normoblasts and
orthochromatophilic normoblasts by day 12 of culture (Fig 1C). At day
12 to 14, greater than 90% to 95% of the cells in culture were
erythroid cells and 5% to 10% of cells morphologically appeared to be
promyelocytes and monocytes (Fig 1C). After 18 to 21 days of culture,
erythroblastic islands formed, each consisting of a central macrophage
surrounded by late orthochromatophilic normoblasts. This was soon
followed by enucleation of 10% to 40% of the erythroid cells, with
enucleation occurring around erythrocyte-macrophage associations (Fig
1D).
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| Fig 1.
In vitro erythropoiesis from normal human
CD34+ progenitor cells. (A) through (D) show
Wright-Giemsa-stained cytospins at serial time intervals of cultures
initiated with purified normal human bone marrow CD34+
cells. Culture conditions used to induce erythroid differentiation are
described in the Materials and Methods. Enucleated RBCs are marked with
arrows. All photographs were taken at original magnification × 200. (A) Day 7; (B) day 9; (C) day 12; (D) day 19.
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At 3 weeks of culture, the enucleated RBCs were separated from the
nucleated erythroid cells and macrophages by staining with a vital DNA
dye, Hoechst 33342, followed by flow cytometry.
Figure 2A shows a FACS analysis of a 3-week
erythroid culture after staining with Hoechst 33342 and a monoclonal
antibody to the erythroid membrane glycoprotein, glycophorin A. Glycophorin A was expressed on the majority of the cells, showing that
nearly all of the cells in the culture were erythroid cells. Forty-two
percent of the cells in this culture were not stained by Hoechst 33342 (Hoechst-negative). Microscopic examination of the sorted cells showed
that Hoechst-negative cells were enucleated erythrocytes (Fig 2B).
Conversely, the sorted Hoechst-positive cells were nucleated
erythrocytes and macrophages in the culture (Fig 2C). Enucleated
erythrocytes could similarly be generated from CD34+ cells
isolated either from cord blood or peripheral blood. CD34+
progenitor cells were also isolated from bone marrow or peripheral blood from SCA patients and differentiated to enucleated RBCs.
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| Fig 2.
Isolation of enucleated erythrocytes from cultures by
flow cytometry. (A) shows a FACS analysis of a 3-week-old culture
initiated from CD34+ cells stained with Hoechst 33342 along the X-axis and glycophorin A along the Y-axis. The two distinct
populations, Hoechst-negative [Hoechst ( )] and Hoechst-positive
[Hoechst (+)] cells were sorted (marked with arrows). (B) and (C)
depict the Wright-Giemsa-stained cytospins of the Hoechst () and
the Hoechst (+) populations, respectively.
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RBC characterization.
Morphologically, most of the Hoechst-negative cells appeared to be
reticulocytes of varying stages of maturity with few mature RBCs.
Differential interference contrast microscopy showed that these
enucleated cells ranged from early polylobulated forms with a pinched
or puckered membrane, resembling normal reticulocytes (enlarged in
inset, Fig 3), to smooth biconcave
discocytes (Fig 3). After staining with acridine orange, a
nucleotide-binding fluorescent dye that emits red fluorescence when
bound to RNA, most Hoechst-negative cells showed a fine reticulum of
red fluorescence, which is consistent with the pattern seen in
reticulocytes17 (data not shown). All Hoechst-negative
cells showed surface expression of glycophorin A (Fig 2A), thus
confirming their erythroid lineage, and the majority of the
Hoechst-negative cells expressed transferrin receptor, consistent with
the expression typically seen on reticulocytes18 (data not
shown).
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| Fig 3.
Differential interference microscopy of in
vitro-generated enucleated erythrocytes from CD34+ cells
from normal human bone marrow cells. CD34+ cells were
cultured under erythroid differentiation conditions and enucleated
cells were FACS sorted as described in the Materials and Methods.
Morphologically, the erythrocytes ranged from early polylobulated forms
with a pinched or puckered membrane, resembling normal reticulocytes
(enlarged in inset), to smooth biconcave discocytes.
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The mean cell volume (MCV) and volume distribution of the erythrocytes
was measured using an aperture-impedance cell-sizing device (Coulter
Counter). The MCV of the erythrocytes generated in vitro
from normal CD34+ cells was 142.7 ± 17.68 µm3 (mean ± standard deviation, n = 4), which was
larger than that of mature erythrocytes isolated from peripheral blood
(which are typically 80 to 96 µm3)19 and more
consistent with volumes of reticulocytes derived from peripheral blood
(mean 131.6 ± 20.1, n = 5).
Globin chain analyses of in vitro derived erythrocytes.
Reverse-phase HPLC analyses were performed to determine the types of
globin chains produced by the RBCs derived in vitro from bone marrow
CD34+ cells (Fig 4).
Hemolysates from the same number of normal umbilical cord blood RBCs
and peripheral blood RBCs were also analyzed as controls for fetal and
adult hemoglobin, respectively. Figure 4A and B depict the HPLC
analysis of normal cord blood and peripheral blood, respectively. The
major -globin cluster chains expressed in cord blood were the fetal
G and A-globins with some adult
-globin (Fig 4A), as expected. The globin chain analysis of normal
adult peripheral blood showed that the major -cluster globin was
-globin (Fig 4B). Figure 4C shows an HPLC analysis of the cultured
enucleated erythrocytes generated from CD34+ cells from
normal bone marrow after 18 days of culture. Nearly all -cluster
globin chains produced are -globin, with minimal amounts of
-globin chains. Thus, the hemoglobin synthesis in the culture
conditions described herein mimics the in vivo adult or postnatal
pattern of globin production rather than the fetal pattern of
-globin synthesis.
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| Fig 4.
Globin chain synthesis by erythrocytes derived in vitro
resembles adult pattern of globin synthesis. (A) and (B) show the reverse-phase HPLC analyses of normal umbilical cord blood and adult
peripheral blood (representing fetal and adult-type globin production),
respectively. (C) shows the same analysis on enucleated erythrocytes
generated in vitro from CD34+ cells from normal bone
marrow and sorted after Hoechst 33342 labeling. The order of appearance
of various globin chains (from left to right) is as follows: -,
 -,  -, AT-, G-, and AI-globin.
The X-axes represent retention time and the Y-axes represent absorbance.
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Transduction of CD34+ cells with a cell surface marker
gene and expression of the gene product in the enucleated RBC progeny.
The potential for introducing genes into progenitor cells and attaining
expression in the resultant erythrocyte progeny was tested as a model
of gene therapy for RBC disorders. Normal human CD34+ cells
were transduced with a retroviral vector, L-tNGFR-SN, carrying a cell
surface reporter, the tNGFR, as a marker gene.14 Transduced cells expressing the reporter gene were identified by labeling cells
with MC192, a monoclonal antibody to rat p75 NGFR.
Figure 5A shows the tNGFR expression of the
CD34+ cells transduced with the L-tNGFR-SN vector
supernatant (solid histogram) 4 days after transduction. Expression of
tNGFR was observed on 44.6% of the cells.
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| Fig 5.
Transduction of CD34+ cells with a cell
surface marker gene and expression of the gene product in the
enucleated RBC progeny. (A) is an FACS analysis of CD34+
cells at day 4 posttransduction with the retroviral vector L-tNGFR-SN (solid histogram) when labeled with the antibody against tNGFR, MC192
(shown on the X-axis). Sham-transduced cells (open histogram) were used
to set gates for the flow cytometry of tNGFR-expressing [tNGFR(+)]
cells and the nonexpressing [tNGFR()] cells. The tNGFR() and
tNGFR(+) cells were subjected to erythroid differentiation and
reanalyzed by three-color FACS analyses at day 18 of culture by
labeling cells with biotinylated MC192 and streptavidin PE, FITC-conjugated anti-glycophorin A, and Hoechst 33342. Cultures derived
from the tNGFR() (B and D) and the tNGFR(+) (C and E) populations
are shown.
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CD34+ cells expressing tNGFR on the surface [tNGFR(+)]
and those not expressing the surface reporter [tNGFR()] were
sorted by flow cytometry 4 days after transduction, and each population was cultured in erythroid differentiation conditions. After 3 weeks in
culture, both the tNGFR(+) and tNGFR() cells were subjected to a
three-color FACS analysis using Hoechst 33342, antihuman glycophorin A
antibody (FITC-labeled), and antirat tNGFR antibody, MC192
(PE-labeled). Figure 5B and C demonstrate that the majority of cells in
both the tNGFR() and tNGFR(+) populations were erythroid cells,
based on surface expression of glycophorin A. Most cells that had been
sorted as tNGFR() at day 4 did not express tNGFR on their
surface at day 18 of culture (Fig 5B), whereas those that had been
sorted as tNGFR(+) at day 4 still expressed tNGFR on their surface at
day 18 of erythroid culture (Fig 5C). Furthermore, whereas tNGFR
expression was absent on the surface of erythrocytes derived from the
untransduced cell population [tNGFR(), fig 5D], tNGFR was
expressed on the surface of 89% of the enucleated RBCs in the
transduced cell population [tNGFR(+), Fig 5E]. Expression of the
tNGFR transgene in the enucleated erythrocytes was detected both by
flow cytometry (Fig 5E) and by immunohistochemistry (data not shown).
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DISCUSSION |
The goals of the present study were to (1) develop a model of in vitro
erythropoiesis from human CD34+ progenitor cells and (2) to
test the potential for insertion of an exogenous gene into
CD34+ progenitor cells and attainment of expression of the
gene in the enucleated RBC progeny.
Production and isolation of a pure population of terminally
differentiated, enucleated RBCs from human CD34+ cells, in
sufficient numbers for biophysical studies and for the study of gene
transfer and expression, is a unique feature of the current model that
has not been previously described.
The most commonly used in vitro assays from CD34+ primitive
progenitor cells result in production of erythroid colonies, composed of early (BFU-E) or late (CFU-E) erythroid progenitors in
methylcellulose or plasma clots.6,7,20-22 However, the
hemoglobinized colonies in semisolid media do not result in terminally
differentiated enucleated erythrocytes. Most liquid long-term cultures
are limited by the presence of heterogenous mixtures of mainly myeloid
cells with arrest of erythropoiesis at the CFU-E
level.23,24 Very high levels of Epo have been reported to
suppress the number of myeloid cells in culture.25,26
Highly purified erythroid colony-forming cells (ECFCs) have been
generated from peripheral blood mononuclear cells (PB-MNC) using a
two-phase culture system.27 Here, PB-MNC that were depleted of platelets, T cells, and myeloid cells27-29 were cultured
in semisolid medium containing IL-3 and Epo for 1 week (phase 1). Thereafter, the nonadherent cells (enriched in ECFC) were harvested from the semisolid cultures and placed in liquid culture containing Epo
to obtain large numbers of CFU-E (phase 2).27 The two-phase culture system was also adapted to generate terminally differentiated cells from PB-MNC.8,30,31 PB-MNC were initially grown in semisolid medium containing either 5637-bladder carcinoma
cell-conditioned medium8,30,31 or
phytohemagglutinin-stimulated leukocyte conditioned medium9
(phase 1). The conditioned media provided erythroid burst-promoting
activity (BPA).24 After 1 week, cells in the semisolid
cultures (enriched in erythroid precursors) were harvested and
terminally differentiated under low oxygen concentrations (5%
O2) in liquid culture containing Epo (phase
2).8,9,30,31
Dexter et al24 had reported terminal erythroid
differentiation in murine long-term bone marrow cultures when anemic
mouse serum was added to the cultures as a source of BPA.
Availability of recombinant cytokines made possible the identification
of BPA effects of a number of cytokines, viz, IL-3, stem cell factor
(SCF), and GM-CSF, etc.32-36 Chelucci et
al37 reported unilineage differentiation of purified
primitive hematopoietic progenitors if high concentrations of Epo along
with low concentrations of GM-CSF and IL-3 were used. However, they
have followed their cultures up to 12 to 14 days and have not reported
terminal RBC differentiation and development of enucleated RBCs. In the
current model, we have used very high concentrations of Epo and low
levels of GM-CSF and IL-337 to culture CD34+
cells, derived either from bone marrow, cord blood, or peripheral blood, to generate terminally differentiated RBCs. We have further isolated the enucleated RBCs from the rest of the erythroid culture by
flow cytometry, based on the use of a DNA-binding dye to isolate cells
that have undergone enucleation.
The RBCs generated in vitro showed different stages of normal
erythrocyte maturation from reticulocytes to mature discocytes. They
had higher mean corpuscular volumes than erythrocytes isolated from
peripheral blood, because the majority of these cells resembled reticulocytes in morphology, RNA staining, and transferrin receptor expression. We have also generated RBCs from bone marrow- and peripheral blood-derived CD34+ cells from individuals with
SCA.
An important feature of the RBCs generated in vitro in the current
model was production of adult -globin (Hb A), with negligible fetal
globin (Hb F) synthesis, mimicking in vivo erythropoiesis. Similarly,
Hb S was produced in RBCs derived from CD34+ cells from
patients with SCA. Because problems in hemoglobinopathies such as SCA
and thalassemia become manifest with adult globin production,1,38 a model with adult-type erythropoiesis is essential to study the pathophysiology of hemoglobinopathies and test
effective therapeutic strategies. Significant Hb F production has been
observed in erythroid bursts grown from CD34+ cells
cultured in semisolid media in vitro, and the amount of Hb F has been
shown to be proportional to the concentrations of cytokines.1,33,39-43 It has also been observed that the
proportion of Hb F in erythroid colonies is inversely proportional to
maturation of the colonies.1,44 The low levels of Hb F
observed in the RBCs generated in vitro in our system could be ascribed
to the very low concentrations of IL-3 and GM-CSF in the culture
conditions, as well to terminal erythroid differentiation.
To examine the potential application of this model to studies of gene
therapy of RBC disorders, we have inserted a cell surface reporter gene
into CD34+ progenitor cells and show expression of the gene
product on the surface of the enucleated RBC progeny. We have also
generated green fluorescent RBCs after transduction of
CD34+ cells with a vector encoding the jelly fish green
fluorescent protein, MND-eGFP-SN45 (data not shown).
Detection of an exogenously inserted gene product in the enucleated
human RBCs after transduction of CD34+ progenitor cells has
not been previously described. The in vitro model of human
erythropoiesis can therefore be used to genetically manipulate
hematopoietic progenitor/stem cells from patients with congenital RBC
defects and test the functional effects of the gene therapy in the
target RBC progeny.
We are currently using this model to study RBC abnormalities in sickle
cell disease and the possibility of reversing these abnormalities by
gene therapy. Efficient ex vivo RBC production could also have
implications for production of RBCs for transfusions, if sufficient
quantities can be generated.
| |
FOOTNOTES |
Submitted November 3, 1997;
accepted January 8, 1998.
Supported by the National Heart, Lung and Blood Institute Grant No.
5P60-HL48484-02, by National Institute of Allergy and Infectious
Diseases Grant No. 5R01-AI23547-10, by the Specialized Center of
Research (SCOR) in Hematopoietic Stem Cell Biology HL9410B, and the J. Connell Gene Therapy Program.
Address reprint requests to Punam Malik, MD, Childrens Hospital Los
Angeles, Mail stop # 62, 4650 Sunset Blvd, Los Angeles, CA 90027;
e-mail: malik{at}hsc.usc.edu.
The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" is accordance with 18 U.S.C. section 1734 solely to indicate this fact.
| |
ACKNOWLEDGMENT |
The authors thank Debbie Gribbons, Clinical Nurse Specialist, and the
nursing staff in the Hematology-Oncology day hospital, Childrens
Hospital Los Angeles, for collecting the phlebotomized blood from
patients with sickle cell anemia; the nursing staff of the Labor and
Delivery and Birthing Center, Kaiser Permanente, Los Angeles for
collecting the cord blood samples; and Takara Shuzo, Inc (Otsu, Japan)
for providing us with the CH-296 fragment of fibronectin.
| |
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Abstract
Introduction
Abstract