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 Previous Article | Table of Contents | Next Article 
Blood, Vol. 91 No. 12 (June 15), 1998:
pp. 4516-4522
Ex Vivo Culture of
CD34+/Lin /DR Cells in
Stroma-Derived Soluble Factors, Interleukin-3, and Macrophage
Inflammatory Protein-1 Maintains Not Only Myeloid But
Also Lymphoid Progenitors in a Novel Switch Culture Assay
By
Jeffrey S. Miller,
Valarie McCullar, and
Catherine M. Verfaillie
From the Department of Medicine, University of Minnesota Cancer
Center, Minneapolis, MN.
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ABSTRACT |
We have demonstrated that long-term culture initiating cells
(LTC-IC) are maintained in a stroma noncontact (SNC) culture where
progenitors are separated from stroma by a microporous membrane and
LTC-IC can proliferate if the culture is supplemented with interleukin-3 (IL-3) and macrophage inflammatory protein-1
(MIP-1). We hypothesize that the same conditions, which result in
LTC-IC proliferation, may also maintain lymphoid progenitors. Natural killer (NK) cells are of lymphoid lineage and a stromal-based culture
can induce CD34+/Lin /DR
cells to differentiate along the NK cell lineage. We developed a
three-step switch culture assay that was required to demonstrate the
persistence of NK progenitors in
CD34+/Lin/DR cells assayed
in SNC cultures supplemented with IL-3 and MIP-1. When
CD34+/Lin/DR progeny from
the SNC culture were plated sequentially into "NK cell progenitor
switch" conditions (contact with stromal ligands, hydrocortisone-containing long-term culture medium, IL-2, IL-7, and
stem cell factor [SCF]) followed by "NK cell differentiation" conditions (contact with stromal ligands, human serum, no
hydrocortisone, and IL-2), significant numbers of
CD56+/CD3 NK resulted, which exhibited
cytotoxic activity against K562 targets. All steps are required because
a switch from SNC cultures with IL-3 and MIP-1 directly to "NK
cell differentiation" conditions failed to yield NK cells suggesting
that critical step(s) in lymphoid commitment were missing. Additional
experiments showed that CD34+/CD33 cells
present after SNC cultures with IL-3 and MIP-1, which contained up
to 30% LTC-IC, are capable of NK outgrowth using the three-step switch
culture. Limiting dilution analysis from these experiments showed a
cloning frequency within the cultured CD34+/CD33 population similar to fresh
sorted CD34+/Lin/DR cells.
However, after addition of FLT-3 ligand, the frequency of primitive
progenitors able to develop along the NK lineage increased 10-fold. In
conclusion, culture of primitive adult marrow progenitors ex vivo in
stroma-derived soluble factors, MIP-1, and IL-3 maintains both very
primitive myeloid (LTC-IC) and lymphoid (NK) progenitors and suggests
that these conditions may support expansion of human hematopoietic stem
cells. Addition of FLT-3 ligand to IL-2, IL-7 SCF, and stromal factors
are important in early stages of NK development.
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INTRODUCTION |
ALTHOUGH PRIMITIVE progenitors of both
myeloid and lymphoid lineage can be found within the CD34 positive bone
marrow population,1-4 it is unclear if ex vivo culture to
expand stem cells or to induce proliferation for retroviral gene
transduction will maintain cells capable of multilineage
differentiation, self-renewal, and engraftment. Cultivation of the CD34
positive, lineage negative, HLA-DR negative/dim population
(CD34+/Lin/DR) in
stromal-dependent long-term culture (LTC) results in differentiation into committed myeloid progenitors and maintenance of long-term culture
initiating cells (LTC-IC).5,6 Although stromal cells in LTC
are a requirement for the maintenance of myeloid progenitors with
LTC-IC capacity, direct contact with intact stromal feeders is not a
requirement for this process. When progenitors are physically separated
from the stroma layer by a microporous membrane (stroma noncontact
culture),
CD34+/Lin/DR LTC-IC
are maintained.7 Moreover, LTC-IC are maintained to a
greater extent under stroma noncontact (SNC) conditions than when
CD34+/Lin/DR cells
were cultured in direct contact with stroma. We have also shown that
addition of macrophage inflammatory protein-1 (MIP-1), a member
of the chemokine family, and the growth promoting cytokine interleukin-3 (IL-3) to SNC culture results in a fourfold to sixfold expansion of LTC-IC after 2 weeks.8-10 Without stroma, no
combination of known growth promoting and growth inhibitory cytokines
could maintain LTC-IC, suggesting that other factors produced by stroma may be essential.
To evaluate lymphoid development, we have developed a modified
long-term marrow culture system, which generates natural killer (NK)
cells from
CD34+/Lin/DR adult
marrow cells, the population known to contain LTC-IC.11 Purified CD34+/Lin/DR
cells are plated directly on allogeneic, irradiated primary marrow stromal feeders with medium containing IL-2. When progenitors are
plated in the absence of IL-2 or in the presence of hydrocortisone, no
NK cell differentiation is seen. However, when
CD34+/Lin/DR cells
are cultured on allogeneic irradiated stroma with IL-2 and in the
absence of hydrocortisone, differentiation of NK cells results.
However, progeny from these cultures are unable to reinitiate secondary
long-term cultures suggesting that cultures do not maintain NK cell
progenitors and lead to terminal NK cell differentiation. The
requirement for direct contact with intact stromal layers distinguishes
this population from more committed progenitors (CD34+/CD7+), which do not require direct
contact with stroma.12 The importance of progenitor-stroma
contact interaction for lymphoid progenitor differentiation has been
described for several lymphoid culture systems and is the basis for the
murine Whitlock-Witte culture.13
Primitive myeloid progenitors can be assessed as blast cell colony
cells, high proliferative potential-colony-forming cell (HPP-CFC) or LTC-IC. Long-term NK
cultures,11,12,14 fetal thymic organ
cultures,15 and human modified B-cell
assays13,16,17 have been used to assess lymphoid capacity.
However, few in vitro assays exist that measure more primitive human
cells with both myeloid and lymphoid capacity. One approach is to
initiate long-term cultures under myeloid "Dexter" conditions
(hydrocortisone containing) followed by a "switch" to conditions
favoring lymphoid growth (removal of hydrocortisone) similar to the
Whitlock-Witte assay. Such an assay would allow recognition of lymphoid
progenitors that are maintained under myeloid conditions and may serve
as a system to study conditions of primitive lymphoid progenitor maintenance. In this report, we describe a novel myeloid/NK cell switch
culture system.
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MATERIALS AND METHODS |
Normal bone marrow.
Bone marrow was obtained from normal donors after informed consent
using guidelines approved by the Committee on the Use of Human Subjects
in Research at the University of Minnesota. Bone marrow mononuclear
cells (BMMNC) were obtained by Ficoll-Hypaque (specific
gravity 1.077) (Sigma Diagnostics, St Louis, MO) density gradient centrifugation.
Purification of primitive progenitors.
BMMNC were enriched for CD34+ cells using an avidin-biotin
column as recommended by the manufacturer (Cellpro, Bothel, WA). Resultant cells were stained with phycoerythrin (PE)-conjugated anti-CD34 antibody (HPCA-2) (Becton Dickinson [BD], San
Jose, CA) for isolation of CD34 positive cells or CD34-biotin (Cellpro) for multicolor sorting as previously described.18
Fluorescein isothiocyanate (FITC)-conjugated antibodies against CD2,
CD3, CD4, CD5, CD7, CD8, CD10, and CD19 were used for the lineage (Lin) cocktail (BD). PE-conjugated anti-HLA-DR (DR) was used and
streptavidin SA670 (GIBCO BRL, Grand Island, NY) as the third
fluorescent color.
Stroma noncontact cultures.
CD34+/Lin/DR cells
were plated in long-term culture medium (LTC medium Iscove's modified
Dulbecco's medium [IMDM] [GIBCO BRL, Grand Island, NY], 12.5%
fetal calf serum [HyClone Laboratories, Logan, UT], 12.5% horse
serum [Stem Cell Technologies, Vancouver, BC], 10-6
hydrocortisone [Upjohn, Kalamazoo, MI]) supplemented with 5 ng/mL IL-3 (R&D Systems, Minneapolis, MN) and 100 ng/mL MIP-1 (R&D Systems) in a collagen-coated Transwell (Costar Corp, Cambridge, MA)
above a preestablished, allogeneic, irradiated (2,500 cGy) stromal
feeder. The Transwell insert (Costar) separates progenitors from stroma
by a 0.45-µm filter.8 At day 7, half of the medium was
removed from the lower well and supplemented with the same medium
supplemented with fresh cytokines. After an additional 7 days, cells
were harvested and inoculated directly into NK cultures or sorted into
CD34+/CD33 and
CD34+/CD33+ populations as previously
described.9
Culture of NK cell progenitors.
NK cell progenitors were plated in direct contact with preestablished
allogeneic irradiated stroma as indicated. NK progenitor maintenance
was tested by plating NK cell progenitors in contact with or separated
from stroma by a Transwell for 5 weeks and further differentiation in
IL-2 alone. The three-step NK cell switch culture incorporates IL-3 and
MIP-1 SNC culture progeny to induce NK cell commitment and further
differentiation (Fig 1). Cultures were maintained in a humidified
atmosphere at 37°C and 5% CO2 and medium was half
changed weekly. Medium was supplemented as indicated with 1,000 U/mL
IL-2 (a gift from Amgen, Thousand Oaks, CA), 10 ng/mL stem cell factor
(SCF), a gift from Amgen), and 10 ng/mL IL-7 (R&D Systems). In the
final culture step, NK medium consisted of 2:1 (vol/vol) Dulbecco's
Modified Eagle Medium (DMEM)/Ham's F12 supplemented with 10% heat
inactivated human AB serum and 1,000 U/mL IL-2 as
described.19
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| Fig 1.
Culture of
CD34+/Lin/DR cells in
stromal-based long-term NK cell culture with IL-2 alone results in NK
cell differentiation without maintenance of CD34+ cells,
committed myeloid progenitors, or lymphoid progenitors capable of
reinitiating long-term NK cell cultures. A sequential culture was
designed to induce commitment and further differentiation of NK cell
progenitors from cultures, which maintain LTC-IC. Fresh CD34+/Lin/DR cells are
plated in Transwell inserts above allogeneic, irradiated stroma in LTC
medium supplemented with IL-3 and MIP-1. After 14 days, progeny are
harvested and plated in direct contact with stroma in the presence or
absence of indicated cytokines for "NK cell progenitor switch"
conditions. After 2 weeks, medium was removed without loss of
nonadherent cells then replated in NK medium with IL-2 alone to further
differentiate NK cells.
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Limiting dilution analysis.
Progenitors were plated in bulk or adapted to culture in 96-well plates
for limiting dilution analysis (22 replicates at four dilutions: 1,200 to 2,400, 400 to 800, 133 to 266, 45 to 90 cells/well).12 Wells were determined as positive by addition of 5,000 51Cr-labeled K562 cells (American Tissue Type Collection
[ATTC], Rockville, MD) resulting in a specific lysis greater than
three standard deviations above spontaneous lysis. The frequency of NK
cell progenitors in each population was calculated as the reciprocal of
the concentration of cells that resulted in 37% negative wells using
Poisson statistics and the weighted mean method.20,21 In
some limiting dilution assays (LDA) experiments, 10 ng/mL
FLT-3 ligand (a gift from Immunex, Seattle, WA) was added. To simplify the LDA switch culture, all cytokines were added to the NK based medium
(after finding no difference between LTC medium and NK-based medium) at
culture initiation and cultures were half changed with NK medium
containing IL-2 alone for the remaining culture period.
Phenotype and cytotoxicity.
Cell surface antigens were determined by direct staining of cells with
mouse monoclonal antibodies. FITC-or PE-coupled antibodies (BD) were
directed at CD2, CD3, CD7, CD8, CD10, CD16, CD19, CD56, and NKB1. FITC-
and PE-coupled isotype matched immunoglobulins were used as controls.
All analyses were performed with a FACS Star Plus flow cytometer (BD)
equipped with a Consort 32 computer (BD). Cytotoxicity
assays were performed in triplicate using K562 (ATTC) and the Raji
(ATTC) cell lines in a 4-hour Cr51 release
assay.22,23
RNA extraction, polymerase chain reaction (PCR), and Southern
blotting.
Progeny of switch cultures were harvested and total mRNA extracted
using RNeasy spin columns according to the manufacturer's recommendations (Qiagen, Santa Clarita, CA). Reverse transcription was
performed as previously described in detail.18 Briefly, samples were subjected to 40 cycles of denaturation at 95°C for 20 seconds, annealing at 55°C for 15 seconds, and extension at 72°C for 1 minute in a Perkin Elmer 480 thermal cycler (Foster City, CA). Oligonucleotide primer sequences were: CD3
5 primer: 5-CTCTGCCTCCCAGCCTCTTT-3; CD3
3 primer: 5-GCGTCGTAGGTGTCCTTGGT-3; CD3
5 primer:
5-AGTTGGCGTT-TGGGGGCAAGATGGTAATGAAGAAA-3; CD3 3
primer: 5-CCCAGGAAACAGGG-AGTCGCAGGGGGACTGGAGAG-3.
Amplified products were size separated on 1.5% agarose gels and
transferred to Hybond N+ nucleic acid transfer membranes (Amersham,
Arlington Heights, IL). Probes were labeled with
32P-deoxyadenosine triphosphate (dATP) using
a TdT 3-end labeling kit (Boehringer Mannheim, Indianapolis, IN)
using probe sequences: CD3 5-ACTGTAGGCCTCCGCCA-3;
CD3 5-TTCT-CACACACTCTTGCCCTCAGG-3.
Statistics.
Results of experimental points obtained from multiple experiments were
reported as mean ± 1 standard error of the mean (SEM). Significance
levels were determined by two-sided Student's t-test analysis.
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RESULTS |
Development of a switch culture assay.
Primitive progenitors can develop along the NK cell lineage by culture
in direct contact with allogeneic stromal feeders and IL-2 (termed
"NK cell differentiation culture"), but this system does not
maintain NK progenitors. Using this model for NK cell development, we
evaluated whether NK cell progenitors were present after SNC cultures
supplemented with IL-3 and MIP-1, conditions known to expand myeloid
LTC-IC. CD34+/Lin/DR
cells were cultured in IL-3 and MIP-1 SNC cultures (n = 6). After 14 days under these conditions, no phenotypic NK cells were identified and
progeny from these cultures were unable to lyse K562 tumor targets
(data not shown). Progeny of IL-3 and MIP-1 SNC cultures were then
evaluated for their capacity to initiate NK cell differentiation
cultures. NK cells could not be generated under these conditions
suggesting that the IL-3 and MIP-1 SNC cultures did not maintain
progenitors of the NK cell lineage or alternatively, that other factors
were missing to induce primitive cells to develop along the NK cell
lineage.
Because early B, T, and NK progenitors require interaction with stroma
for survival and differentiation,12,24,25 we introduced an
intermediate culture step that promotes direct contact with stromal
feeders in an attempt to induce NK progenitor commitment from IL-3 and
MIP-1 SNC LTC-IC expansion cultures (Fig
1, "NK cell progenitor switch conditions"). The addition of
direct contact without additional cytokines was insufficient to induce
NK progenitor commitment. IL-2, IL-7, or the combination of IL-2 and
IL-7 poorly induced NK cell commitment, as measured after the final
culture step with IL-2 alone (Fig 2).
Therefore, in addition to IL-2, IL-7, and stromal-derived contact
factors, we evaluated the addition of SCF, which has importance in
lymphoid commitment and expansion.15,26-29 SCF alone did
not induce commitment of previously cultured cells to give rise to NK
cell progeny. In contrast, the combination of IL-2, IL-7, and SCF
induced NK cell progenitor commitment resulting in significant
generation of NK cells after a final switch to conditions favoring NK
cell differentiation (Fig 2). NK cells were phenotypically similar to
those already described from fresh CD34+/Lin/DR cells
(data not shown) and exhibited characteristic function in cytotoxicity
assays (Fig 3, left panel).
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| Fig 2.
IL-2, IL-7, SCF, and stromal ligands generate NK cells
from progeny of IL-3 and MIP-1 SNC cultures.
CD34+/Lin/DR cells were
initially plated in SNC cultures for 14 days resulting in 47 ±7.3-fold cell expansion. These expanded cells (1 to 4 × 105 from 2,000 to 4,000 initial
CD34+/Lin/DR cells) were
plated in direct contact with stroma and the indicated cytokines for NK
cell progenitor switch conditions. In a final step, conditions were
changed again to those favoring NK cell differentiation. The
combination of IL-2, IL-7, and SCF was best to induce NK cell
progenitor commitment (n = 8) compared with no cytokines or other
cytokines tested (n = 4).
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| Fig 3.
NK cell progeny resulting from the three-step switch
culture exhibited characteristic cytotoxicity against tumor targets. CD34+/Lin/DR cells were
plated in IL-3 and MIP-1 SNC culture for 14 days. Resultant bulk
cultured cells (left panel, n = 4) or sorted
CD34+/CD33 cells (right panel, n = 6)
were switched to conditions favoring NK cell development. NK cell
progenitor commitment was induced by IL-2, IL-7, SCF, and stromal
ligands. After a final NK cell expansion in IL-2-containing NK medium,
cytotoxicity was tested against K562 ( ) and Raji ( ). Lytic
activity for bulk switched or CD34+/CD33
cells was similar to that observed from fresh
CD34+/Lin/DR cells plated
in long-term NK cell cultures for 5 weeks.
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CD34+/CD33 cells from IL-3 and
MIP-1 SNC cultures give rise to NK cells in switch
culture.
We have previously shown that CD34+/CD33
cells present in 14-day IL-3 and MIP-1 SNC cultures are highly
enriched for LTC-IC, with a cloning frequency up to 30%.9
We next assessed whether lymphoid cells are present after IL-3 and
MIP-1 SNC cultures. After 14-day IL-3 and MIP-1 SNC culture,
CD34+/Lin/DR progeny
did not express any marker of lymphoid progenitors (CD2, CD7,
CD10)12,30 or mature lymphocytes (CD3, CD8, CD10, CD19, or
CD56). When CD34+/CD33 and
CD34+/CD33+ cells from
CD34+/Lin/DR-initiated IL-3 and MIP-1
SNC cultures were purified by flow cytometry and plated directly into
NK cell differentiation cultures, no NK cells resulted (n = 6). In
contrast, culture under NK cell progenitor switch conditions followed
by conditions supporting NK cell differentiation resulted in
significant NK cell generation. CD34+/CD33 cells gave rise to
significantly more NK cells than CD34+/CD33+
cells (154 ± 64-fold expansion v 18 ± 9-fold expansion,
n = 9; P = .044). The number of NK cells generated by
CD34+/CD33 cells was similar to that
reported by us for fresh
CD34+/Lin/DR
cells.11 These cells exhibited cytolytic function in
cytotoxicity assays similar to that derived from CD34 positive marrow
populations (Fig 3, right panel). The phenotype of these 9-week
cultured NK cells was similar to the phenotype of NK cells derived from
fresh CD34+/Lin/DR
cells. Although NK cells expressed other lymphoid markers (CD2, CD7,
CD8), switch cultures do not give rise to mature CD3+ T
cells or CD19+ B cells (Table
1). To estimate progenitor frequency,
CD34+/CD33 cells selected after IL-3 and
MIP-1 SNC cultures were then plated in a modified limiting dilution
assay incorporating NK cell progenitor switch conditions. Similar to
the cloning frequency observed with fresh
CD34+/Lin/DR
cells,12 the cloning frequency of resorted
CD34+/CD33 cells was approximately 0.1%
(n = 3).
Evaluation of "switch" culture conditions.
The addition of stromal ligands, IL-2, IL-7, and SCF was sufficient to
induce NK cell progenitor commitment from
CD34+/CD33 cells cultured for 14 days in
IL-3 and MIP-1 SNC cultures, but it was still uncertain how these
conditions contributed to NK cell generation. Further experiments were
performed to address these questions. NK cell progenitors were defined
as cells with the capacity to give rise to NK cells when switched to
IL-2-containing NK medium under NK cell differentiation conditions. To
fully test NK cell progenitor survival conditions, culture duration was
lengthened to 5 weeks. Freshly sorted
CD34+/Lin/DR
progenitors were plated in LTC medium with or without additional cytokines in direct contact with stroma or separated from stroma by a
Transwell membrane. After the 5-week culture, medium was changed to
conditions that support terminal NK cell differentiation (direct
contact, human serum, IL-2). NK cell progenitors did not survive in LTC
medium alone whether progenitors were in contact with or separated from
stroma during the initial culture period. Addition of IL-7 alone failed
to increase NK cell progenitor survival (data not shown). However, IL-2
and especially the combination of IL-2 and IL-7 increased NK cell
progenitor survival, but only if
CD34+/Lin/DR cells
were in contact with stroma for the 5-week culture period (Fig 4).
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| Fig 4.
Defined cytokines and direct contact with stroma are
sufficient for survival of NK progenitors. Ten thousand
CD34+/Lin/DR cells were
plated in direct contact with stroma (black bars) or suspended above
stroma in a Transwell insert (white bars) in hydrocortisone containing
LTC medium and the indicated cytokines (n = 4). After 5 weeks,
conditions were switched to those favoring NK cell terminal
differentiation. Starting
CD34+/Lin/DR cells plated
in direct contact with stroma were switched by removal of all LTC
medium, nonadherent cells were pelleted, resuspended in NK medium, and
replated on the initial stroma layer. Progeny of
CD34+/Lin/DR cells cultured
in a Transwell were harvested, resuspended in NK medium, and replated
on the stromal layer below. After 4 to 5 weeks in NK medium, cells were
harvested, counted, and phenotyped. NK cells resulting from this final
step defined NK cell progenitors surviving conditions during the first
culture period. IL-2 + IL-7 in direct contact with stroma ligands
resulted in significantly greater NK cell progenitor maintenance
compared with no cytokines (P = .025) or the same cytokines
without contact with stroma ligands (P = .019).
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We next addressed whether NK switch conditions could induce NK
progenitor development from a more undifferentiated cell. Fresh CD34+/Lin/DR cells
were plated directly in LDA under NK cell differentiation conditions
with IL-2 containing medium alone or modified to incorporate contact-mediated NK cell progenitor switch conditions with LTC medium
supplemented with IL-2, IL-7, and SCF (n = 3). NK cell progenitor
cloning frequency was similar between the two conditions and in no case
did LDA's incorporating NK cell progenitor switch conditions result in
a higher cloning frequency suggesting that these conditions did not
increase commitment of clonogenic NK cell progenitors. An alternative
explanation for the increased generation of NK cells in the switch
culture is that the NK cell progenitor switch conditions actually
expand NK cell progenitors. This was tested by determining the NK cell
cloning frequency in the
CD34+/Lin/DR starting
population (day 0 LDA) and comparing this with the cloning frequency of
CD34+/Lin/DR cells
cultured for 14 days in a bulk well under NK cell progenitor switch
conditions before plating into LDA (n = 4 for all conditions). The day
0 cloning frequency of fresh
CD34+/Lin/DR cells
was 0.04% ± 0.01%. Bulk culture of the progeny of
CD34+/Lin/DR cells
under NK cell progenitor switch conditions followed by LDA (plated
according to the initial number inoculated at day 0) resulted a 28 ± 4.6-fold increase in cloning frequency compared with the day 0 LDA (Fig 5). The importance of
hydrocortisone in NK cell progenitor expansion (LTC medium + IL2, IL-7,
SCF) was also tested in LDA. Significantly less NK cell progenitor
expansion was observed when hydrocortisone only was eliminated from the culture resulting in only a 5 ± 1.2-fold increase in cloning
frequency compared with the day 0 LDA (Fig 5).
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| Fig 5.
Direct contact with stromal ligands, IL-2, IL-7, SCF, and
hydrocortisone induces NK cell progenitor expansion. Fresh
CD34+/Lin/DR cells were
plated into functional LDAs under long-term NK cell culture conditions
with IL-2 alone to determine the day 0 cloning frequency, which for
each experiment was assigned the day 0 baseline (white bars). The
absolute cloning frequency for day 0 was 0.04% ± 0.01%. NK cell
progenitor expansion was evaluated by plating 20,000 fresh
CD34+/Lin/DR cells in
direct contact with stroma in LTC medium with (black bars) or without
(hatched bars) hydrocortisone. After 14 days, progeny of these cultures
were trypsinized and plated into LDA in NK medium. The cloning
frequency was determined based on the number of
CD34+/Lin/DR cells
initially inoculated into culture and is reported by experiment compared with the same donor's day 0 LDA.
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FLT-3 ligand induces commitment to the NK lineage.
In experiments described above,
CD34+/CD33 cells derived from IL-3 and
MIP-1 SNC cultures give rise to NK cells in a switch culture assay
using IL2, IL7, and SCF. However, we could not show that these switch
conditions could increase the frequency of progenitors to develop along
the NK cell lineage. In addition, the approximately 0.1% cloning
frequency for cultured CD34+/CD33 cells
was lower than expected. Several possibilities may explain this low
cloning frequency. Either the IL-3 and MIP-1 SNC cultured CD34+/CD33 cells poorly support lymphoid
progenitor survival or alternatively, the switch culture readout with
IL-2, IL-7, and SCF was still inadequate to efficiently induce NK
commitment. FLT-3 ligand has been shown to be an important primitive
acting cytokine and FLT-3 receptors are selectively found on human CD34
positive cells.31,32 Therefore, we added FLT-3 ligand to
our previously tested cytokines (IL-2, IL-7, and SCF) and plated 14 day
IL-3 and MIP-1 SNC cultured CD34+/CD33 cells in limiting dilution.
With the addition of FLT-3 ligand to the switch culture assay, the
cloning frequency of NK cells increased 10-fold to 1.2% ± 0.4% (n = 4) compared with cultures where FLT-3 ligand was not present. These
data further support the notion that IL-3, MIP-1, and
stromal-derived factors maintain cells capable of lymphoid
differentiation and addition of FLT-3 ligand to the switch culture
assay induces progenitors to differentiate along the NK cell lineage.
NK cells from FLT-3 ligand switch cultures were
CD56+/CD3, coexpressed other lymphoid
markers (CD2, CD7, CD8), and were able to lyse K562 and Raji targets
(data not shown). CD3 and CD3 transcripts were consistently
detected in progeny of switch cultures (n = 6), lymphoid genes that are
expressed by IL-2-stimulated mature NK cells.33 In
addition, a small percentage of NK cells (0% to 8%, n = 6) derived
from switch cultures also expressed the killer inhibitory receptor
(KIR), NKB1, one of a family of lymphocyte receptors found on NK cells,
which recognize class I major histocompatibility complex
(MHC).34 Taken together, these data support
the notion that cells derived from switch cultures are of lymphoid
origin.
| |
DISCUSSION |
Stem cell self-renewal, proliferation, and myeloid versus lymphoid
commitment involves complex interactions with the microenvironment through soluble factors and in direct contact with stromal ligands. There has been great interest in exploiting these techniques to cultivate human stem cells for transplantation. Until now, there was no
evidence that multilineage progenitors are maintained after ex vivo
culture, which also maintain LTC-IC. We developed methods to determine
if primitive cells with lymphoid potential are maintained in long-term
culture. Sequential modifications of the myeloid long-term culture were
used to assess NK cell progenitors as a measure of lymphoid capacity.
CD34+/Lin/DR cells
were cultured in stroma noncontact culture with MIP-1 and IL-3,
conditions known to maintain myeloid LTC-IC. These conditions do not
promote differentiation of CD34 positive cells into phenotypically
identifiable CD2, CD7, or CD10 lymphoid progenitors or mature NK cells.
However, a switch to contact with stromal ligands, IL-2, IL-7, and SCF
was able to generate NK cells. The NK cell progenitor capacity was
mainly found in the CD34+/CD33
population, which has also been shown to be enriched for LTC-IC. In
contrast to the high cloning frequency of LTC-IC within this population
(up to 30%), the NK cell progenitor cloning frequency was
significantly less. This raises the possibility that despite the
ability to initiate myeloid long-term cultures at high frequency, the
number of CD34+/CD33 progenitors, which
also maintain the capacity to generate lymphoid cells, is significantly
lower. This is in agreement with studies by Lemieux et al35
who developed a murine long-term culture switch assay in which murine
marrow is grown in limiting dilutions for 4 weeks under myeloid
conditions. Subsequently, a switch to lymphoid conditions and
evaluation of B-cell progeny identified progenitors capable of both
myeloid and lymphoid growth. The cloning frequency of cells with both
myeloid and lymphoid capacity was approximately 10-fold to 15-fold
lower than that of cells capable of initiating myeloid long-term
cultures alone. The lower frequency of NK cell progenitors in our
system, even after addition of FLT-3 ligand, which increased NK
progenitor cloning frequency by 10-fold, may be the result of a low
number of primitive cells capable of lymphoid differentiation.
Alternatively, in vitro conditions may still be inadequate to induce
differentiation of primitive cells toward the NK cell lineage.
Glucocorticoids have been shown to suppress mature lymphocytes
including NK cells36 and are absent from Whitlock-Witte
cultures. Therefore, we did not expect to find that hydrocortisone was
important to induce NK cell progenitor expansion as demonstrated in our LDAs. How hydrocortisone effects expansion of NK progenitors is unknown, but may be indirectly related to effects on
stroma.37 Glucocorticoids increase SCF in normal marrow
fibroblasts.38 However, this alone may not account for our
findings given the excess exogenous SCF added to cultures. It is
possible that the membrane bound form of SCF is increased and required
for expanding NK cell progenitors. Glucocorticoids may also affect
expression of other cytokines such as leukemia inhibitory factor
produced by marrow endothelial cells.39 Finally,
glucocorticoids alter the sulfation pattern of glycosaminoglycans in
the extracellular matrix, which may affect progenitor and cytokine
binding.40
The importance of direct contact with stroma for myeloid and lymphoid
differentiation seems to be divergent. LTC-IC do not require contact
with stroma for maintenance, although soluble factors produced by
stroma, such as glycosaminoglycans, are important.41 Further work from our group suggests that direct contact with stroma
through  1 integrins inhibits myeloid progenitor proliferation suggesting that contact with stroma may function as a negative regulator of myelopoiesis.42 In contrast, for B-cell
progenitors or NK progenitors, physical separation from stroma results
in substantially decreased proliferation and differentiation of
progenitors.12,24 The observation that
CD34+/CD33 cells obtained after 2 weeks
of cytokine supplemented stroma noncontact culture, which would
presumable select against lymphoid progenitors, can give rise to NK
cells when conditions are switched to facilitate direct contact with
stroma supports the notion that contact with stroma is not required for
survival of NK progenitors, but contact is required in the
differentiation process. However, without further data, the precise
mechanism of progenitor differentiation (recruitment, maintenance, and
proliferation) in cytokine supplemented, stromal based switch cultures
cannot not be determined.
In summary, we developed a switch culture assay that allows
differentiation of
CD34+/Lin/DR cells
cultured in "myeloid" IL-3, and MIP-1 SNC cultures to differentiate into NK cells. Therefore, ex vivo culture in stromal soluble factors, IL-3 and MIP-1, can maintain cells capable of both
myeloid and lymphoid differentiation. To demonstrate whether myeloid
and lymphoid progenitors are derived from a single
CD34+/CD33 cell or from committed
myeloid and lymphoid progenitors will require use of single cell
deposition assays or retroviral marking.
| |
FOOTNOTES |
Submitted October 3, 1997;
accepted February 3, 1998.
Supported in part by National Institutes of Health Grants No.
R29-HL-55417, R01-HL-54039, and PO1-CA-65493. We also acknowledge the
support of the University of Minnesota Bone Marrow Transplant Research
Fund and the University of Minnesota Academic Health Center.
Address reprint requests to Jeffrey S. Miller, MD, Division of
Hematology, Box 806, University of Minnesota Cancer Center, Harvard St
at East River Rd, Minneapolis, MN 55455.
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 Brad Anderson for his help with flow cytometry and
Jeanne Lund for her excellent technical help in PCR assays.
| |
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R |
Abstract
Introduction
Abstract