Myelodysplastic syndromes (MDS) are a heterogeneous group of clonal disorders characterized by ineffective hematopoiesis and frequent progression to acute myeloid leukemia. Within MDS, 5q− syndrome constitutes a distinct clinical entity characterized by an isolated deletion of the long arm of chromosome 5 (5q−), a relatively good prognosis, and infrequent transformation to acute leukemia. The cell of origin in 5q− syndrome as well as in other 5q-deleted MDS patients has not been established, but evidence for involvement of multiple myeloid (but not lymphoid) lineages has suggested that a myeloid-restricted progenitor rather than a pluripotent (lympho-myeloid) stem cell might be the primary target in most patients. Although in 9 patients no evidence of peripheral blood T-cell and only 1 case of B-cell involvement was found, the data herein support that 5q deletions occur in hematopoietic stem cells (HSCs) with a combined lympho-myeloid potential. First, in all investigated patients a minimum of 94% of cells in the minor CD34+CD38 HSC compartment were 5q deleted as determined by fluorescence in situ hybridization. Second, in 3 of 5 patients 5q aberrations were detected in a large fraction (25% to 90%) of purified CD34+CD19+ pro-B cells. Furthermore, extensive functional characterization with regard to responsiveness to early-acting cytokines, long-term culture-initiating cells, and nonobese diabetic/severe combined immunodeficiency repopulating cells supported that MDS HSCs in 5q-deleted patients are CD34+CD38, but inefficient at reconstituting hematopoiesis.

Myelodysplastic syndromes (MDS) represent a heterogeneous group of clonal hematopoietic disorders characterized by hyperproliferative but ineffective hematopoiesis, as reflected in dysplastic changes in myeloid cell lineages and different degrees of anemia, leukopenia, and thrombocytopenia.1-3 Overall, the prognosis of MDS patients is poor, with high mortality resulting from infections and hemorrhage due to refractory cytopenias, and with 25% to 30% of the cases showing progression to acute myeloid leukemia (AML).

Fully 40% to 60% of all MDS patients have identifiable chromosomal aberrations at diagnosis,1-8 providing not only evidence for the clonal nature of MDS, but also a means of staging the cell types involved in the clone through standard karyotyping or interphase fluorescence in situ hybridization (FISH).9,10 FISH has complemented X-linked restriction fragment length polymorphism (RFLP) analysis and detection of oncogene (in particularras) mutations to determine at what stage in the hematopoietic hierarchy the transformation in MDS occurs.11-13 

Two alternative and complementary models have been proposed to explain the apparent lineage restriction and heterogeneity of leukemias,14-16 also applicable to MDS. The first interprets the lineage restriction as a consequence of transformation occurring at different levels of commitment in the hematopoietic hierarchy. In contrast, the other model proposes that transformation occurs at the level of a multipotent progenitor/stem cell and that the apparent lineage restriction is a result of the transforming event itself. Clonality studies of myeloid and lymphoid cells have revealed variable results with regard to the potential involvement of multipotent (lympho-myeloid) stem cells in MDS (reviewed in Heaney and Golde,2 Knuutila,13 and Weimar et al17). Although technical issues such as skewed methylation patterns in RFLP studies and potential impurities in lymphocyte preparations might explain some of the discrepancies,2,11,13,17 in most (but not all) cases, the MDS clone appears to involve the myeloid but not lymphoid cell lineages.9,12,18-35 Because MDS, in contrast to the stem cell disease chronic myelogenous leukemia (CML),36 also rarely transforms into acute lymphoblastic leukemia, it has been proposed that the transformation event in MDS occurs most frequently at the level of a committed myeloid progenitor (reviewed in Heaney and Golde2).

Although there is agreement that multiple myeloid cell lineages invariably are involved in the MDS clone, whether lymphocytes are also derived from this clone might depend in part on the specific chromosomal aberration(s) involved. The most powerful tool to enumerate specific chromosomal aberrations in various cell lineages is interphase FISH applied to purified cell populations. In the case of trisomy 8 and monosomy 7, a large number of such FISH studies have suggested that only in a very few cases are the lymphocytes involved in these aberrant clones.9,25,27 29-35 

Within MDS, 5q− syndrome constitutes a distinct clinical entity characterized by an isolated deletion of the long arm of chromosome 5 (del(5q) or 5q−), female predominance, macrocytic anemia, modest neutropenia, normal or high platelets, hypolobular megakaryocytes, and a low risk of leukemic transformation.37-41 Clonality studies performed on MDS patients with 5q deletions have revealed no cases of lymphocyte involvement.23,24,28,35,38-40 Whether pluripotent hematopoietic stem cells (HSCs) are involved in the 5q− clone could be important for the use of autologous stem cell transplantation in these patients.42 That lymphocytes appear not to be involved in the 5q-deleted clone does not exclude HSCs as primary targets of 5q deletions. Such a scenario would be feasible if the transformed pluripotent stem cell had lost or reduced its ability to differentiate toward lymphocytes. Thus, addressing the potential involvement of lympho-myeloid HSCs in 5q− syndrome would require a different approach than investigating only the involvement of mature lymphocytes and myeloid cells.

Because multipotent reconstituting HSCs in normal as well as AML bone marrow (BM) have been demonstrated recently to reside almost exclusively in the CD34+CD38 compartment, representing less than 0.1% of normal BM cells,43-46 we purified CD34+CD38 cells from MDS patients with a known 5q deletion. In all patients, FISH analysis demonstrated that virtually all CD34+CD38 cells belonged to the 5q-deleted clone, and functional human stem cell assays supported that 5q-deleted MDS stem cells are CD34+CD38 but are ineffective in reconstituting hematopoiesis. Finally, in some patients a large fraction of pro-B (CD34+CD19+) progenitors also belonged to the 5q− clone. Thus, a lympho-myeloid HSC appears to be the primary target of 5q deletions in MDS.

Patients

BM and peripheral blood (PB) samples from 12 MDS patients and 10 normal subjects were collected at the Hematology Sections at Karolinska and Huddinge Hospitals, Sahlgrenska University/Östra Hospital, and University Hospital of Lund after obtaining informed consent and with approval of the ethics committees at the medical faculties of the respective hospitals. Patient characteristics are provided in Table 1. All patients had a confirmed diagnosis of MDS according to the French-American-British classification47 and a confirmed 5q deletion. Patient no. 12 had been treated with chemotherapy (tioguanin + arabinosylcytosine + daunorubicin) plus granulocyte-macrophage colony-stimulating factor (GM-CSF) in 1996 because of progression with greater than 20% blasts in the BM (refractory anemia with excess blasts in transformation; RAEBt). Since then, the clinical picture had been stable without additional treatment.

Table 1.

Clinical, hematologic, and cytogenetic characteristics of 5q-deleted MDS patients

Sex/ageFABBM blastHb, g/LWBC, 109/LPlt, 109/LKaryotypeTreatment
OngoingPrevious
Patients with 5q− syndrome 
 1 F/73 RA < 5% 110 7.5 211 del(5)(q13q33) Epo — 
 2 F/73 RA < 5% 72 2.8 275 del(5)(q13q33) — — 
 3 F/83 RA < 5% 76 5.3 426 del(5)(q14) — — 
 4 F/82 RA < 5% 102 4.7 439 del(5)(q15-21) — — 
 5 M/75 RA < 5% 151 8.9 189 del(5)(q15) G-CSF/Epo — 
Other MDS patients with 5q deletions 
 6 M/73 RAEB 10% 72 1.4 150 del(5)(q23) — — 
 7 F/81 RA < 5% 114 7.2 320 del(5)(q22q35)del(6) — — 
 8 F/83 RA < 5% 104 4.5 414 del(5)(q13q33)del(20) — Epo 
 9 F/87 RA < 5% 109 4.6 382 del(5)(q13q33)+8 — — 
10 F/83 RAEB 7% 100 5.2 279 del(5)(q*)del(11)del(2) — — 
11 F/72 RAEB 17% 101 9.9 201 del(5)(q22)+8 Prednisolone — 
12 F/68 RAEB 6% 123 8.0 80 del(5)(q15)+2mar —  
Sex/ageFABBM blastHb, g/LWBC, 109/LPlt, 109/LKaryotypeTreatment
OngoingPrevious
Patients with 5q− syndrome 
 1 F/73 RA < 5% 110 7.5 211 del(5)(q13q33) Epo — 
 2 F/73 RA < 5% 72 2.8 275 del(5)(q13q33) — — 
 3 F/83 RA < 5% 76 5.3 426 del(5)(q14) — — 
 4 F/82 RA < 5% 102 4.7 439 del(5)(q15-21) — — 
 5 M/75 RA < 5% 151 8.9 189 del(5)(q15) G-CSF/Epo — 
Other MDS patients with 5q deletions 
 6 M/73 RAEB 10% 72 1.4 150 del(5)(q23) — — 
 7 F/81 RA < 5% 114 7.2 320 del(5)(q22q35)del(6) — — 
 8 F/83 RA < 5% 104 4.5 414 del(5)(q13q33)del(20) — Epo 
 9 F/87 RA < 5% 109 4.6 382 del(5)(q13q33)+8 — — 
10 F/83 RAEB 7% 100 5.2 279 del(5)(q*)del(11)del(2) — — 
11 F/72 RAEB 17% 101 9.9 201 del(5)(q22)+8 Prednisolone — 
12 F/68 RAEB 6% 123 8.0 80 del(5)(q15)+2mar —  

BM morphology and blood values of patients were investigated in connection with BM aspiration for the present studies. Patients 1-4, 6, and 9-11 were dependent on red cell transfusions at the time of the studies.

MDS indicates myelodysplastic syndromes; FAB, French-American-British classification; BM, bone marrow; RA, refractory anemia; RAEB, refractory anemia with excess blasts.

*

The specific breakpoints on the long arm of chromosome 5 could not be established in this patient.

GM-CSF plus tioguanin + ara-C + daunorubicin (see “Materials and methods”).

Purification of BM and PB cell populations

BM cells were obtained from the posterior iliac crest. BM and PB mononuclear cells (MNCs) were isolated by Ficoll-Hypaque (Nycomed, Oslo, Norway) gradient centrifugation. Positive selection of BM CD34+ cells was performed using a MACS (magnetically activated cell sorting) CD34 isolation kit (Miltenyi Biotec, Bergish Gladbach, Germany), as described previously.48Purity of CD34+ cells was 76% to 94% (average 88%). CD34-enriched cells were incubated with CD38-phycoerythrin (PE) and CD34–fluorescein isothiocyanate (FITC) monoclonal antibodies (MoAbs) or with isotype-matched irrelevant control antibodies (all from Becton Dickinson, San Jose, CA). The 75% of CD34+ cells expressing the highest levels of CD38 (CD34+CD38+) and CD34+CD38 cells were sorted on a FACSVantage Cell Sorter (Becton Dickinson). As described previously,48a conservative approach was taken so that only the “lowest” CD34+CD38 cells (mean, 3.7%; range, 2.5% to 6.1%) were sorted (Figure 1; R4 gate), in an effort to obtain a highly enriched population of primitive progenitors. Both CD34+ cell populations reproducibly had a purity of greater than 98% with regard to CD34 expression.

Fig. 1.

CD34 and CD38 expression profile on CD34-enriched cells from a typical patient with 5q− syndrome.

CD34-enriched cells from patient no. 4 were stained with CD34-FITC and CD38-PE antibody or isotype control antibody. In this patient, CD34+CD38+ and CD34+CD38 cells represented 91.4% and 8.6% of CD34+ cells, respectively. Also shown are the sorting gates for CD34+CD38+ (R3) and CD34+CD38 (R4) cells.

Fig. 1.

CD34 and CD38 expression profile on CD34-enriched cells from a typical patient with 5q− syndrome.

CD34-enriched cells from patient no. 4 were stained with CD34-FITC and CD38-PE antibody or isotype control antibody. In this patient, CD34+CD38+ and CD34+CD38 cells represented 91.4% and 8.6% of CD34+ cells, respectively. Also shown are the sorting gates for CD34+CD38+ (R3) and CD34+CD38 (R4) cells.

Close modal

BM CD34+CD19+CD14CD15(pro-B) and CD34+CD33+ (myeloid) progenitors were sorted after incubation with allophycocyanin (APC)– or FITC-conjugated CD34 MoAbs, PE-conjugated CD19 or CD33 MoAbs, and FITC-conjugated CD14 and CD15 MoAbs for 15 minutes on ice. PB CD3+, CD15+, and CD19+ cell populations were sorted after incubation of MNCs with CD3-FITC (Becton Dickinson), CD15-FITC (Pharmingen, San Diego, CA), and CD19-PE (Becton Dickinson) MoAbs respectively.

Fluorescence in situ hybridization

Cytospin preparations of various cell populations were pretreated as described previously.49 Briefly, slides were fixed in methanol/acetic acid 3:1 for 15 minutes, dehydrated in a graded (70% to 100%) series of ethanol, and air dried. The slides were then fixed in 1% neutral buffered formalin for 5 minutes, followed by microwave heat treatment in sodium citrate buffer, pH 6.0, for 2 × 5 minutes; 0.01% proteinase K (type VIII; Sigma, St. Louis, MO) digestion for 5 minutes; and postfixation in neutral buffered formalin for 5 minutes before being dehydrated and air dried. The LSI EGRI/D5S721:D5S23 dual-color DNA probe (Vysis Inc, Downers Grove, IL) was used for hybridization according to the manufacturer's instructions. After hybridization, the slides were washed in 1 × SSC for 5 minutes at 72°C, followed by washes in 0.05% TBS-Tween for 3 minutes at room temperature and counterstaining with DAPI (4,6-diamino-2-phenylinol, 1 μg/mL; Sigma). The Vysis dual-color probe hybridizes to band 5q31 (SpectrumOrange LSI EGRI) and to band 5p15.2 (SpectrumGreen LSI D5S721:D5S23) of chromosome 5. In the nuclei of normal cells, the probe appears as 4 distinct signals, 2 orange and 2 green (2O + 2G), whereas patients with del(5q) typically show 1O + 2G. Occasionally the probe may appear as other combinations of orange and green signals, which are excluded when calculating the frequency of 5q-deleted and normal cells in a specific cell population. Unless otherwise stated, 100 to 600 cells were evaluated for each cell population. For all cell populations investigated, cells from normal subjects were treated the same way and used to determine the cutoff value for the FISH method; they always showed less than 5% 1O + 2G cells. When validating the specificity of FISH results on fluorescence-activated cell sorter (FACS)-purified cell populations from MDS patients, one also must consider the likelihood of 1O + 2G cells originating from impurities. On the basis of the purity of sorted populations (greater than 90%) and with the cutoff value of the FISH method, we generally considered findings of less than 10% to 15% 1O + 2G cells (depending on cell populations) to be negative or inconclusive.

Hematopoietic growth factors

Recombinant human (rh) megakaryocyte growth and development factor (MGDF), rh granulocyte colony-stimulating factor (G-CSF), rh stem cell factor (SCF), rh interleukin-3 (IL-3), and rh GM-CSF were generously provided by Amgen Corp. (Thousand Oaks, CA). Rh erythropoietin (Epo) was supplied by Boehringer Mannheim Corp (Mannheim, Germany) and rh fH3 ligand (FL) by Immunex (Seattle, WA).

Expansion cultures

CD34+CD38+ and CD34+CD38 cells from MDS patients and healthy subjects were seeded at 3000 to 10 000 cells/mL in Iscove's modified Dulbecco's medium (IMDM) (BioWhittaker, Walkersville, MD) supplemented with 20% fetal calf serum (FCS; BioWhittaker), 10−4 mol/L 2-mercaptoethanol (Sigma), and cytokines. After 10 to 12 days, the cells were counted and cytospins were examined morphologically after May-Grünwald-Giemsa staining (Sigma) or were subjected to FISH analysis.

Single-cell clonogenic assay

As described previously,50CD34+CD38+ and CD34+CD38 cells were seeded in Terasaki plates (Nunc, Kamstrup, Denmark) at a density of one cell per well in 20 μL serum-depleted medium (X-vivo 15; BioWhittaker) supplemented with 1% bovine serum albumin (Stem Cell Technologies Inc., Vancouver, Canada), 10−4 mol/L 2-mercaptoethanol, and cytokines. Wells were scored for cell growth after 11 to 13 days of incubation.

Long-term culture-initiating assay

Long-term cultures were established with normal BM MNCs, irradiated, and maintained according to previously described methods.48,51 CD34+CD38+(750-7500) and CD34+CD38 (150-750) cells from MDS patients and healthy adults were added to stroma layers (same stroma for MDS and normal controls), and cocultures were maintained by weekly 50% medium changes (Myelocult H5100; Stem Cell Technologies). After 5 weeks, nonadherent and adherent cells were plated in methylcellulose cultures, as described,48 supplemented with MGDF, G-CSF, SCF, FL (all at 25 ng/mL), Epo (5 U/mL), and IL-3 (10 ng/mL). Colony-forming cells (CFC; readout of long-term culture-initiating [LTC-IC] assay) were scored after an additional 12 to 14 days in culture.

Nonobese diabetic/severe combined immunodeficiency (NOD/SCID) repopulating assay

NOD/LtSz-SCID mice (originally from The Jackson Laboratory, Bar Harbor, ME) were bred and housed under sterile conditions in microisolator cages and given autoclaved food and acidified drinking water. Mice were irradiated with 350 to 375 cGy from a137Cs source at 8 to 12 weeks of age and thereafter were given prophylactic ciprofloxacin (100 μg/mL) in the drinking water until analysis (6-8 weeks after transplantation). Tail-vein transplantation/injection of hematopoietic cells suspended in 0.5 to 1.0 mL of medium was performed within 4 hours of irradiation. If hematopoietic cells transplanted were less than 105, 1 × 106 irradiated accessory cells (human MNCs or CD34-depleted cells) were coinjected. Femora and tibiae were collected after asphyxiation with CO2, and engraftment was investigated as described previously.45 52 Briefly, cells were stained with anti-human CD45-FITC and CD71-FITC antibodies as well as antimouse CD45.1(Ly 5.1)-PE. Untransplanted mice (negative controls) and mixtures of 0.1% to 0.5% human cells in murine BM (positive controls) were always included. If engraftment was detected by CD45/71 analysis (detection level less than 0.05%), staining with anti–CD34-FITC, CD19-PE, CD33-PE/CD66b-FITC, and CD15-PE was performed, including antihuman CD45–peridinin chlorophyll protein and antimouse CD45.1 biotin plus streptavidin-APC. BM cells (5 × 104 to 1 × 105) were plated in methylcellulose and human-specific cytokines (GM-CSF, 50 ng/mL; IL-3, 25 ng/mL; and SCF, 25 ng/mL) plus Epo at 5 U/mL, resulting in no colony formation of BM from untransplanted NOD/SCID mice (L.N. and S.E.W.J., unpublished observations). CFU-GM and burst-forming unit-erythroid were scored after 10 to 14 days and transferred to slides for FISH analysis.

Targeting of the 5q deletion to the CD34+CD38 stem cell compartment

In 5 patients with refractory anemia (RA), the 5q deletion was the only diagnosed chromosomal aberration (Table 1), and all of these fulfilled the diagnostic criteria for the 5q− syndrome.39 Of the remaining 7 patients, 1 had an isolated 5q deletion but was of the RAEB subgroup, whereas the others had a 5q deletion combined with other chromosomal aberrations. Morphologically identified blasts in BM aspirates varied from less than 5% (8 of 12 patients) to 17% (patient no. 11).

Although CD34+CD38 cells represent only approximately 1 in 1000 normal BM cells, almost all stem cell activity resides in this minor subfraction, both in normal and AML subjects.43-46 All 4 patients with 5q− syndrome investigated showed a similar distribution between CD34+CD38+ and CD34+CD38 cells as observed in normal BM, with the CD34+CD38 subpopulation representing 10% or less of the CD34+CD38+ cells (Table2, Figure 1). Similarly, in all 5 investigated patients with 5q deletions combined with other chromosomal aberrations, CD34+CD38 cells represented a minority of the total CD34+ cells. Only in patient no. 6 did CD34+CD38 cells represent a major fraction of the CD34+ cells. It is noteworthy that this patient had as many as 24% CD34+ cells in the BM MNCs, whereas CD34+ cells did not exceed 6% in any of the other patients included in this study. Among CD34+CD38+ cells, 88% to 98% had 5q deletions (Table 3). Strikingly, in 8 of the 9 investigated patients, more than 98% of the CD34+CD38 cells carried the 5q deletion, whereas 94% in the last patient (no. 4) were involved (Table 3, Figure2). Thus, in MDS patients with both 5q− syndrome and 5q deletion in combination with other chromosomal aberrations, the vast majority of candidate stem cells appear to be derived from the 5q-deleted clone.

Table 2.

Frequency of CD34+, CD34+CD38+, and CD34+CD38 progenitors in MDS and normal bone marrow mononuclear cells

Patient% CD34+% CD34+CD38+% CD34+CD38
1.0 0.94 0.07 
1.3 1.26 0.04  
5.4 4.94 0.46 
0.7 0.63 0.07  
24 12.2 11.8 
3.6 3.51 0.09  
5.9 4.87 1.03 
10 5.0 4.58 0.43  
11 6.2 5.86 0.28 
12 2.8 2.11 0.71 
Controls 2.0 (0.3) 1.89 (0.3) 0.11 (0.03) 
Patient% CD34+% CD34+CD38+% CD34+CD38
1.0 0.94 0.07 
1.3 1.26 0.04  
5.4 4.94 0.46 
0.7 0.63 0.07  
24 12.2 11.8 
3.6 3.51 0.09  
5.9 4.87 1.03 
10 5.0 4.58 0.43  
11 6.2 5.86 0.28 
12 2.8 2.11 0.71 
Controls 2.0 (0.3) 1.89 (0.3) 0.11 (0.03) 

The relative frequencies of CD34+, CD34+CD38+, and CD34+CD38 cells in BM MNCs were determined at the time of BM aspirations for the present studies.

The values for normal controls (n = 10) represent the mean (SEM), analyzed in parallel.

Table 3.

Frequency of 5q deletions in CD34+, CD34+CD38+, and CD34+CD38 cells

Patient% cells with 5q deletions
CD34+ cellsCD34+CD38+cellsCD34+CD38 cells
nd 98 98 
nd 97 98  
97 98 94  
94 nd nd 
nd 99 > 99  
963-150 88 > 99 
893-150 95 > 99  
10 98 98 99 
11 nd 93 99  
12 95 98 99  
Mean (SEM) 95 (1.3) 96 (1.2) 98 (1.0) 
Patient% cells with 5q deletions
CD34+ cellsCD34+CD38+cellsCD34+CD38 cells
nd 98 98 
nd 97 98  
97 98 94  
94 nd nd 
nd 99 > 99  
963-150 88 > 99 
893-150 95 > 99  
10 98 98 99 
11 nd 93 99  
12 95 98 99  
Mean (SEM) 95 (1.3) 96 (1.2) 98 (1.0) 

CD34+CD38+ and CD34+CD38 cells were purified as described in “Materials and methods” and subsequently transferred to slides by cytospin centrifugation before being analyzed by FISH. Normal BM CD34+, CD34+CD38+, and CD34+CD38 cells from 2 individuals were sorted and analyzed by FISH in an identical manner, and the mean percentage of 1O + 2G cells was 3.2%.

nd indicates not determined.

F3-150

Fewer than 100 cells counted.

Fig. 2.

FISH analysis of CD34+CD38 candidate stem cells from a patient with 5q− syndrome.

BM CD34+CD38 cells were isolated from a normal donor (A) and patient no. 1 with 5q− syndrome (B) and subjected to FISH analysis as described in “Materials and methods.” The nuclei of normal cells appear as 2 green (5p) and 2 orange (5q), whereas 5q-deleted cells have 2 green signals and 1 orange signal.

Fig. 2.

FISH analysis of CD34+CD38 candidate stem cells from a patient with 5q− syndrome.

BM CD34+CD38 cells were isolated from a normal donor (A) and patient no. 1 with 5q− syndrome (B) and subjected to FISH analysis as described in “Materials and methods.” The nuclei of normal cells appear as 2 green (5p) and 2 orange (5q), whereas 5q-deleted cells have 2 green signals and 1 orange signal.

Close modal

Demonstration of 5q deletions in lymphoid progenitor cells but not mature lymphocytes

Apparently in contrast to the finding that virtually all cells in the phenotypically defined stem cell compartment had the 5q deletion, previous studies had stated that 5q deletions are restricted to myeloid cells and do not involve mature lymphocytes.23,24,28,35,38,39 In the present studies (Table 4), a large fraction of PB CD15+ myeloid cells in all patients were 5q deleted (51% to 99%), whereas the findings on T cells in all patients were within the expected normal range (when corrected for purity of the population and the cutoff value for the FISH method). It is noteworthy that in patient no. 4, a large fraction (30% and 33%; examined on 2 different occasions) of PB CD19+ cells were 5q deleted, whereas B cells in the remaining patients were within the expected normal range. Thus, with the exception of B cells in 1 of 9 patients, our findings of 5q deletions in mature myeloid but not lymphoid cells confirmed those of previous studies.23,24,28 35 Thus, we hypothesized 2 potential explanations for the apparent involvement of HSCs, but not mature lymphocytes, in the 5q− clone: (1) The 5q deletion in multipotent HSCs is incompatible with lymphoid commitment; or (2) the 5q deletion is incompatible with or disadvantageous for lymphocyte maturation.

Table 4.

5q status in purified lymphoid and myeloid cell populations in peripheral blood

Patient% 5q− cells
CD15+CD3+CD19+
854-150 24-150 
94 
93 2  
97 324-151 
51 nd 
934-150 3  
654-150 124-150 
11 99 
12 99 9  
Mean (SEM) 86 (5.3) 3 (0.6) 8 (2.8) 
Patient% 5q− cells
CD15+CD3+CD19+
854-150 24-150 
94 
93 2  
97 324-151 
51 nd 
934-150 3  
654-150 124-150 
11 99 
12 99 9  
Mean (SEM) 86 (5.3) 3 (0.6) 8 (2.8) 

The frequencies of 5q− (1O + 2G) cells were investigated in FACS-purified myeloid and lymphoid populations from PB. PB from 2 normal individuals was analyzed in an identical manner, and the mean percentages of 1O + 2G cells were 1.6% for CD15+, 2.4% for CD3+, and 4.2% for CD19+cells.

nd indicates not determined.

F4-150

Fewer than 100 cells counted.

F4-151

Mean of 2 separate experiments.

To distinguish between these possibilities, we sought to purify the earliest identifiable lymphoid progenitors from 5q-deleted MDS BM. Probably because of the myeloid hyperplasia in these patients, the frequencies of pro-T (CD34+CD7+) and pro-B (CD34+CD19+) cell progenitors were very low when compared with those of normal subjects (L.N. and S.E.W.J., unpublished observations). Thus, to obtain enough purified cells to perform meaningful FISH analysis, we could investigate only pro-B cells (Table 5). These pro-B cells were sorted based on coexpression of CD34 and CD19 and also lack of myeloid cell surface antigens (Figure 3). Five of the 9 patients investigated revealed distinct CD34+CD19+ pro-B cells sufficient to allow meaningful sorting. In 3 patients (2 with 5q− syndrome), a sizeable fraction of CD34+CD19+ cells with 5q deletion (67%, 90%, and 25% for patients 2, 4, and 9, respectively) was identified. The majority of CD34+CD33+ myeloid progenitors in all investigated patients had the 5q deletion (Table 5). Finally, in one patient (no. 1), we sorted a distinct CD34+CD7+ pro–T-cell population representing 7% of the total CD34+ cell population, of which 98% had the 5q deletion (L.N. and S.E.W.J., unpublished observations). Thus, the finding of the 5q deletion in lymphoid-committed as well as myeloid-committed progenitor cells lends further support to the theory that the 5q deletion is of multipotent (lympho-myeloid) stem cell origin.

Table 5.

5q status in purified myeloid and B lymphoid progenitor subpopulations in bone marrow

PatientCD34+CD33+CD34+CD19+
% of CD34+% 5q−% of CD34+% 5q−
 2 nd nd 2.0 67 (54)5-150 
 3 85 94 05-151 na 
 4 58 99 6.0 905-152 
 5 nd nd 0.2 6  
 6 83 >99 05-151 na 
 8 46 (63)5-150 76 2.6 0 (36)5-150 
 9 nd nd 4.0 25  
11 27 99 05-151 na 
12 18 98 05-151 na  
Mean (SEM) 53 (11.5) 94 (3.8) 3.1 (1.1) 37 (17.0) 
PatientCD34+CD33+CD34+CD19+
% of CD34+% 5q−% of CD34+% 5q−
 2 nd nd 2.0 67 (54)5-150 
 3 85 94 05-151 na 
 4 58 99 6.0 905-152 
 5 nd nd 0.2 6  
 6 83 >99 05-151 na 
 8 46 (63)5-150 76 2.6 0 (36)5-150 
 9 nd nd 4.0 25  
11 27 99 05-151 na 
12 18 98 05-151 na  
Mean (SEM) 53 (11.5) 94 (3.8) 3.1 (1.1) 37 (17.0) 

The frequency and 5q status of purified myeloid (CD34+CD33+) and pro-B (CD34+CD19+) progenitor cell subpopulations were investigated in 5q− deleted MDS patients. Corresponding normal BM populations were isolated from 2 individuals. The mean percentages of 1O + 2G cells were 5.0% and 2.9% for normal CD34+CD33+ and CD34+CD19+ cells, respectively.

nd indicates not determined; na, not applicable.

F5-150

Fewer than 100 cells counted (counted cells are shown in parentheses).

F5-151

Subpopulation too small for sorting.

F5-152

Mean of 2 separate experiments performed with an interval of 12 months.

Fig. 3.

Isolation of CD34+CD19+ pro-B cells from a patient with 5q− syndrome.

FACS profile shows CD19 (PE) versus myeloid (CD14/15-FITC) antigen expression on BM cells from patient no. 2, gated on CD34 (APC)-positive BM cells. Note the lack of coexpression of CD19 and myeloid antigens. In this patient, CD34+CD19+ cells represented 2% of the CD34+ cells, and 67% of these cells were 5q− according to FISH analysis.

Fig. 3.

Isolation of CD34+CD19+ pro-B cells from a patient with 5q− syndrome.

FACS profile shows CD19 (PE) versus myeloid (CD14/15-FITC) antigen expression on BM cells from patient no. 2, gated on CD34 (APC)-positive BM cells. Note the lack of coexpression of CD19 and myeloid antigens. In this patient, CD34+CD19+ cells represented 2% of the CD34+ cells, and 67% of these cells were 5q− according to FISH analysis.

Close modal

Functional characterization of the CD34+CD38 candidate stem cell compartment in MDS patients with 5q deletions

The development of better functional stem cell assays has facilitated the identification and characterization of human stem cells in recent years. Among these are in vitro assays of purified candidate stem cells revealing characteristic patterns of responsiveness to early-acting cytokines53 and reconstitution of hematopoiesis in long-term in vitro stroma-supported cultures or in in vivo xenograft models.54-57 

CD34+CD38+ and CD34+CD38 cells were purified from 5 patients and investigated for their responsiveness to a predetermined optimal combination of cytokines (Table 6). In 4 of the patients (nos. 4, 7, 8, and 10), CD34+CD38 cells cultured for 10 to 14 days maintained a much higher frequency of immature/blast cells than CD34+CD38+ cells, comparable to normal donors, supporting the more primitive nature of CD34+CD38 cells. However, the in vitro expansion potential of both the CD34+CD38+ and CD34+CD38 cells in all of these patients was markedly lower than that of the parallel normal controls, and most of the cells derived from both populations had 5q deletions (Table 6). However, it is interesting that in most patients (with the exception of patient no. 12; discussed later), a much higher frequency of cells with normal 5q status was produced in culture than observed in the starting CD34+CD38+ populations, suggesting a proliferative advantage of cells with a normal 5q status. In the CD34+CD38 populations, a similar tendency was observed for patient no. 8. In the last patient (no. 12), whose BM in all assays showed a unique and hyperresponsive pattern, the CD34+CD38+ cells also maintained a high level of blast cells following culture, and the expansion potential of the CD34+CD38 cells was somewhat higher than that of the normal control. Almost all cells in both populations from this patient contained the 5q deletion.

Table 6.

In vitro cytokine-stimulated growth of CD34+CD38+ and CD34+CD38 cells

PatientCD34+CD38+cellsCD34+CD38 cells
Fold expansion (% of normal)% blasts (normal)% 5q−Fold expansion (% of normal)% blasts (normal)% 5q−
268  (25) 2  (1) 91 15  (23) 42  (73) 96  
377  (38) 7  (nd) 42 42  (6) 30  (nd) 97  
181  (18) 3  (nd) 67 7  (1) 18  (35) 69  
10 17  (nd) 0  (nd) 73 9  (4) 89  (74) 99  
12 202  (31) 16  (3) 98 522  (124) 11  (nd) 99 
PatientCD34+CD38+cellsCD34+CD38 cells
Fold expansion (% of normal)% blasts (normal)% 5q−Fold expansion (% of normal)% blasts (normal)% 5q−
268  (25) 2  (1) 91 15  (23) 42  (73) 96  
377  (38) 7  (nd) 42 42  (6) 30  (nd) 97  
181  (18) 3  (nd) 67 7  (1) 18  (35) 69  
10 17  (nd) 0  (nd) 73 9  (4) 89  (74) 99  
12 202  (31) 16  (3) 98 522  (124) 11  (nd) 99 

CD34+CD38+ and CD34+CD38 cells were cultured in FCS-containing medium in the presence of SCF, FL, MGDF, IL-3, G-CSF, GM-CSF (all at 25 ng/mL), and Epo (5 U/mL). After 10 to 14 days of incubation, cellular expansion was established and cytospin preparations were made for morphologic and FISH analysis. Purified CD34+CD38+ and CD34+CD38 cells from normal volunteers were investigated in parallel in all experiments. FISH analysis of normal cells showed a mean of 1% (n = 2) 1O + 2G cells for CD34+CD38 and 1.3% (n = 3) for CD34+CD38+ cells. Expansion of CD34+CD38+ and CD34+CD38 cells from normal donors varied from 650-fold to 1085-fold and from 64-fold to 755-fold, respectively.

nd indicates not determined.

We next investigated the responsiveness of CD34+CD38+ and CD34+CD38 progenitors to the early-acting cytokines SCF, FL, and MGDF. Normal human CD34+CD38 stem cells show a unique response pattern to these cytokines, in that a combination of all 3 optimally recruits CD34+CD38 cells into proliferation, whereas SCF+FL in the absence of MGDF has little or no such ability.58 CD34+CD38 cells isolated from patients 4, 7, 8, and 10 all showed such a normal response pattern (Figure 4), whereas CD34+CD38+ cells (such as their normal counterparts) showed a higher response to SCF+FL in the absence of MGDF (L.N. and S.E.W.J., unpublished observations). Again, the CD34+CD38 cells isolated from patient 12 displayed enhanced responsiveness, in particular to SCF+FL, when compared with the other patients as well as normal controls.

Fig. 4.

Responsiveness of CD34+CD38MDS cells to early-acting cytokines.

CD34+CD38 cells were plated at the single-cell level as described in “Materials and methods” and cultured in 3 different cytokine combinations: a = SCF + FL; b = SCF + FL + MGDF; and c = cocktail (SCF + FL + MGDF + IL-3 + G-CSF + GM-CSF + Epo). Five normal subjects were used as controls. Wells were scored for total clones per 120 wells and for size (3-50 cells and more than 50 cells) after 11 to 13 days of incubation. No clones were observed for MDS patients 7 and 8 in response to cytokine combination “a.” In general, the clones formed from CD34+CD38cells were too small to allow FISH analysis.

Fig. 4.

Responsiveness of CD34+CD38MDS cells to early-acting cytokines.

CD34+CD38 cells were plated at the single-cell level as described in “Materials and methods” and cultured in 3 different cytokine combinations: a = SCF + FL; b = SCF + FL + MGDF; and c = cocktail (SCF + FL + MGDF + IL-3 + G-CSF + GM-CSF + Epo). Five normal subjects were used as controls. Wells were scored for total clones per 120 wells and for size (3-50 cells and more than 50 cells) after 11 to 13 days of incubation. No clones were observed for MDS patients 7 and 8 in response to cytokine combination “a.” In general, the clones formed from CD34+CD38cells were too small to allow FISH analysis.

Close modal

The CD34+CD38+ cell population from all 5 patients (and the normal controls) contained little or no LTC-IC activity (Figure 5). At variance with the normal donors, CD34+CD38 cells from patients 4, 7, 8, and 10 contained little or no LTC-IC activity, even when plated at 5-fold higher cell numbers than the normal control. In striking contrast, CD34+CD38 cells from patient no. 12 had greater than 20-fold more LTC-IC activity than the normal control population, and all (12 of 12) investigated colonies were 5q deleted, again supporting the hyperresponsiveness of the 5q-deleted CD34+CD38 cells in this patient.

Fig. 5.

LTC-IC activity of CD34+CD38+and CD34+CD38 cells in 5q− MDS patients.

Five-week LTC-IC activity of MDS BM CD34+CD38+cells (A) and CD34+CD38 cells (B) was evaluated as described in “Materials and methods.” CD34+CD38+ and CD34+CD38 cells isolated from normal subjects were included as controls. After 5 weeks of culture, the number of CFCs produced was evaluated in methylcellulose, as described in “Materials and methods.” Results are the means of 3 to 6 replicate wells from each cell population and patient.

Fig. 5.

LTC-IC activity of CD34+CD38+and CD34+CD38 cells in 5q− MDS patients.

Five-week LTC-IC activity of MDS BM CD34+CD38+cells (A) and CD34+CD38 cells (B) was evaluated as described in “Materials and methods.” CD34+CD38+ and CD34+CD38 cells isolated from normal subjects were included as controls. After 5 weeks of culture, the number of CFCs produced was evaluated in methylcellulose, as described in “Materials and methods.” Results are the means of 3 to 6 replicate wells from each cell population and patient.

Close modal

Samples from 7 5q-deleted patients (nos. 3, 4, 6, 7, 8, 11, and 12) were transplanted into sublethally irradiated mice, either as CD34+ cells (250 000-700 000 per mouse) or as purified CD34+CD38 cells (6000-17 000 per mouse). In agreement with the cells' inability to achieve long-term reconstitution in vitro, no mice transplanted with cells from patients 3, 4, 6, 7, 8, or 11 showed any signs of human reconstitution (as determined by FACS and human colony formation; L.N. and S.E.W.J., unpublished observations). However, mice receiving transplants of 700 000 CD34+ cells from patient no. 12 showed as much as 12% human (CD45) engraftment (Figure6A). Most reconstituted cells expressed the myeloid markers CD15 and/or CD33 (Figure 6B). Human CD45+CD15+ cells were purified from the murine BM and, when investigated by FISH, all proved to be 5q deleted (256 of 256 evaluated cells).

Fig. 6.

Exclusive myeloid repopulation by 5q-deleted NOD/SCID reconstituting stem cells.

FACS profile shows BM from 4 pooled NOD/SCID mice each having transplantation with 700 000 CD34+ cells isolated from MDS patient no. 12. (A) BM cells were stained with antimouse CD45.1-APC (Ly 5.1) and antihuman CD45-FITC. Human CD45+ cells constituted 12% of the whole mouse BM. (B) Coexpression of CD15 and CD33 on human CD45+ cells. BM was gated on huCD45+ cells and investigated for the expression of huCD15 and huCD33. Note that virtually all cells expressed myeloid markers, as confirmed by the absence of CD19 expression (data not shown).

Fig. 6.

Exclusive myeloid repopulation by 5q-deleted NOD/SCID reconstituting stem cells.

FACS profile shows BM from 4 pooled NOD/SCID mice each having transplantation with 700 000 CD34+ cells isolated from MDS patient no. 12. (A) BM cells were stained with antimouse CD45.1-APC (Ly 5.1) and antihuman CD45-FITC. Human CD45+ cells constituted 12% of the whole mouse BM. (B) Coexpression of CD15 and CD33 on human CD45+ cells. BM was gated on huCD45+ cells and investigated for the expression of huCD15 and huCD33. Note that virtually all cells expressed myeloid markers, as confirmed by the absence of CD19 expression (data not shown).

Close modal

Identification of the cell of origin in MDS not only should facilitate a better understanding of MDS pathogenesis, but also could have important therapeutic implications. Currently, allogeneic stem cell transplantation represents the only curative treatment for MDS.59 However, because of the advanced age of most MDS patients and limited donor availability, only a small fraction of MDS patients are eligible for this option. As a consequence, autologous stem cell transplantation has become a new therapeutic alternative pursued in MDS,42 in which the status and involvement of the reconstituting stem cell pool could be of crucial importance to the clinical outcome.

Most studies exploring the potential involvement of HSCs in MDS have done so by investigating to what degree the lymphoid as well as myeloid cell lineages are involved in the malignant clone. As outlined in the “Introduction,” such studies have predominantly concluded that in most MDS patients, lymphocytes do not appear to be derived from the malignant clone.9,23,25-31,33,35 This appears particularly clear when chromosomal aberrations are used as markers for the clonal disease.9,25,27,28,30-32,34,35 An alternative and less explored avenue of establishing whether HSCs are transformed in MDS is to investigate whether highly purified HSC populations belong to the transformed clone or not. Whereas FISH analyses of purified HSC populations from AML patients have revealed cytogenetically aberrant cells in the stem cell compartment,60,61 a recent study of MDS patients with trisomy 8 demonstrated that the stem cell compartment was not part of the +8 clone.62 In striking contrast, we here provide data to support that in MDS patients with a 5q deletion, virtually all cells in the HSC compartment appear to be involved in the 5q-deleted clone, although evidence for mature T cells with 5q deletions could not be obtained in any of the 10 investigated patients, and in the case of B cells, in only 1 patient (no. 9). Despite this, multiple lines of evidence supported that primitive lympho-myeloid HSCs represent the cell of origin for 5q deletions: (1) There is massive involvement (in most patients 99% or more) of the minor CD34+CD38 HSC compartment. (2) The presence of a large fraction of 5q-deleted CD34+CD19+pro-B cells was found in 3 of 5 investigated patients and of pro-T cells (CD34+CD7+) in 1 investigated patient. In 1 patient (no. 4), both CD34+CD19+ pro-B cells and CD19+ B cells were found to be involved on 2 separate occasions. (3) Extensive functional characterization suggested that CD34+CD38 cells represent the HSC compartment in 5q-deleted MDS, as demonstrated previously in normal and AML subjects.43-46 58 

As expected, given that the nature of the disease is one of ineffective hematopoiesis, the 5q-deleted HSCs (with one notable exception, patient no. 12) were inefficient at reconstituting hematopoiesis (in vitro as well as in vivo). Although the control subjects used in these studies were considerably younger than the investigated MDS patients, the high number of cells used in the LTC assay suggests a dramatic reduction in stem cell activity in these patients. However, in future studies it will be important to use age-matched controls and to further increase the number of input cells in these assays. It will also be important to assay CD34cells for potential stem cell activity, although in patient no. 12 the stem cell activity resided in the CD34+CD38population. In agreement with the finding that most CD34+CD38 cells are 5q deleted, the frequency of normal CD34+CD38 HSCs in 5q-deleted patients appears to be very low. Thus, phenotypic, cytogenetic, and functional studies strongly implicate involvement of the CD34+CD38 HSC compartment in MDS with 5q deletions. This is in striking contrast to the lack of +8 HSCs in MDS patients with trisomy 8.62 The only notable methodologic difference between the studies was that Saitoh et al sorted HSCs based on coexpression of CD34 and Thy1,62 63 whereas we studied CD34+CD38 cells. However, because these populations in BM have been demonstrated to largely overlap functionally and phenotypically, this is unlikely to explain the contrasting conclusions reached.

Because MDS are heterogeneous, the different findings in patients with trisomy 8 and 5q deletions could be explained in that the clonal disease originates in committed myeloid progenitors in patients with trisomy 8 and in pluripotent HSCs in 5q-deleted patients. Based on previous studies, it has been proposed that the neoplastic event in most MDS patients occurs at a committed myeloid progenitor level.2 However, the basis for proposing primary transformation events in MDS occurring in myeloid-restricted progenitors has been the lack of evidence for lymphocyte involvement in most cases.2,9,12,18-23;25-31,33,35 Because our results as well as previous studies suggest that mature lymphocytes are not derived from the 5q-deleted clone,23,24,28 35 del(5q) could also have been predicted to occur predominantly in myeloid-restricted progenitors. Thus, on the basis of our findings, we would rather propose that HSCs could be the cell of origin in many cases of MDS and that direct studies of highly purified HSCs will be an important avenue to establish this.

There are multiple possible explanations for why B and T cells in MDS patients with 5q deletions appear not to be derived from the 5q-deleted HSCs. Because reconstituting common lymphoid progenitors have been identified64,65 and lymphoid progenitors can be long-lived,66 it is possible that the B and T cells are derived from lymphoid-restricted progenitors generated before the 5q deletion. Alternatively, B and T cells might be produced from a low fraction of normal stem cells. Regardless, the lack of lymphopenia in 5q− patients suggests an efficient compensatory mechanism for lymphocyte production by “normal” hematopoietic cells in these patients. It is important to emphasize that because of the limitations intrinsic to the methods used in this study (FACS and FISH) as well as in other studies, it is impossible to conclude or exclude that a minor fraction of B and T cells are derived from the 5q-deleted clone. In fact, several studies of MDS patients have suggested that a low fraction of T and, in particular, B cells might be involved in the malignant clone (reviewed in Knuutila13). We propose that 5q-deleted stem cells are either deficient in their ability to differentiate toward mature lymphocytes or that these are efficiently deleted. It is noteworthy that similar findings, compatible with deficient lymphocyte (in particular T-cell) differentiation, have been reported recently for CML.67 

Before these studies, we expected that the del(5q) FISH analysis on cells in the CD34+CD38 HSC compartment might prove more heterogeneous in patients with multiple aberrations than in the more distinct group of 5q− syndrome. However, also in all 5 patients with a complex karyotype, a minimum of 99% of the CD34+CD38 cells proved to have the 5q deletion. This suggests that 5q deletions frequently represent an early event in MDS transformation.

Autologous transplantation has been launched as a new and potentially curative treatment for MDS.42 In that regard, it has been argued that a key challenge is to obtain normal stem cell grafts uncontaminated with transformed stem cells.2 Although the presence of lymphoid as well as, in some cases, myeloid cells with a normal 5q karyotype argues for the likely coexistence of normal HSCs, the finding that a majority of HSCs in 5q-deleted MDS might carry the 5q deletion and have the same phenotype as normal HSCs suggests that purification and selection for normal HSCs will prove difficult.

We thank Drs Janet Nichol and Graham Molineux (both of Amgen) and Stewart Lyman (of Immunex) for generous contributions of cytokines for these studies. The expert advice and assistance of David Bryder and Anna Fossum in the NOD/SCID analysis; Gunilla Gärdebring, Carl-Magnus Högerkorp, and Sverker Segrén in cell sorting; and Lilian Wittman, Eva Gynnstam, Irene Persson, and Kristina Sundgren in mouse work are highly appreciated. We also thank Lisa Palm for help with cryopreservation. We are particularly grateful to Bertil Johansson (Department of Clinical Genetics) for helpful advice and educating discussions and to Drs John E. Dick and Connie J. Eaves for crucial advice during the establishment of the NOD/SCID assay. We also thank all patients and bone marrow volunteers for their contributions; the staff at the Department of Hematology for assistance with the aspirations; Inge Olsson, P. G. Nilsson, Jan Westin, Bengt Sallerfors, Ingemar Winqvist, Rolf Billström, Tor Olofsson, Ingunn Dybedal, Ewa Sitnicka, Yutaka Sasaki, and Corinne Rusterholz for discussions or critical review of the manuscript; and Stig Rödjer and Nils Mauritzon for providing crucial bone marrow samples. Prof Stefan Karlsson's contributions through helpful discussions and critical review of the manuscript are highly appreciated.

Supported by grants from the Swedish Cancer Society (4148-B98-01XAB and 3794-B98-03XAB), the Cancer Society in Stockholm (98:111 and 99:151), The Craaford Foundation, Georg Danielsson Foundation, Harald Jeansson Foundation, Nilsson's Cancer Foundation, Åke Wiberg Foundation, Anna-Lisa and Sven-Eric Lundgren Foundation, John and Augusta Persson Foundation, John Persson Foundation, Tobias Foundation, Government Public Health (ALF) Grants, Skåne Landsting, and the Medical Faculty, University of Lund.

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.

1
Lowenthal
 
RM
Marsden
 
KA
Myelodysplastic syndromes.
Int J Hematol.
65
1997
319
338
2
Heaney
 
ML
Golde
 
DW
Myelodysplasia.
N Engl J Med.
340
1999
1649
1660
3
Greenberg
 
P
Myelodysplastic syndrome.
Hematology, Basic Principles and Practice.
Hoffman
 
R
Benz
 
EJ
Shattil
 
SJ
et al
2000
1106
1129
Churchill Livingstone
Philadelphia, Pa
4
Heim
 
S
Mitelman
 
F
Chromosome abnormalities in the myelodysplastic syndromes.
Clin Haematol.
15
1986
1003
1021
5
Yunis
 
JJ
Lobell
 
M
Arnesen
 
MA
et al
Refined chromosome study helps define prognostic subgroups in most patients with primary myelodysplastic syndrome and acute myelogenous leukaemia.
Br J Haematol.
68
1988
189
194
6
Nowell
 
PC
Chromosome abnormalities in myelodysplastic syndromes.
Semin Oncol.
19
1992
25
33
7
Parlier
 
V
van Melle
 
G
Beris
 
P
et al
Hematologic, clinical, and cytogenetic analysis in 109 patients with primary myelodysplastic syndrome: prognostic significance of morphology and chromosome findings.
Cancer Genet Cytogenet.
78
1994
219
231
8
Haase
 
D
Fonatsch
 
C
Freund
 
M
et al
Cytogenetic findings in 179 patients with myelodysplastic syndromes.
Ann Hematol.
70
1995
171
187
9
Kibbelaar
 
RE
van Kamp
 
H
Dreef
 
EJ
et al
Combined immunophenotyping and DNA in situ hybridization to study lineage involvement in patients with myelodysplastic syndromes.
Blood.
79
1992
1823
1828
10
Le Beau
 
MM
Larson
 
RA
Cytogenetics and neoplasia, new techniques to detect chromosomal abnormalities.
Hematology, Basic Principles and Practice.
Hoffman
 
R
Benz
 
EJ
Shattil
 
SJ
et al
2000
848
870
Churchill Livingstone
Philadelphia, Pa
11
Gale
 
RE
Wainscoat
 
JS
Clonal analysis using X-linked DNA polymorphisms.
Br J Haematol.
85
1993
2
8
12
Janssen
 
JW
Buschle
 
M
Layton
 
M
et al
Clonal analysis of myelodysplastic syndromes: evidence of multipotent stem cell origin.
Blood.
73
1989
248
254
13
Knuutila
 
S
Lineage specificity in haematological neoplasms.
Br J Haematol.
96
1997
2
11
14
Fialkow
 
PJ
Singer
 
JW
Adamson
 
JW
et al
Acute nonlymphocytic leukemia: heterogeneity of stem cell origin.
Blood.
57
1981
1068
1073
15
McCulloch
 
EA
Stem cells in normal and leukemic hemopoiesis (Henry Stratton Lecture, 1982).
Blood.
62
1983
1
13
16
Stock
 
W
Pathobiology of acute myeloid leukemia.
Hematology, Basic Principles and Practice.
Hoffman
 
R
Benz
 
EJ
Shattil
 
SJ
et al
2000
979
999
Churchill Livingstone
Philadelphia, Pa
17
Weimar
 
IS
Bourhis
 
JH
De Gast
 
GC
Gerritsen
 
WR
Clonality in myelodysplastic syndromes.
Leuk Lymphoma.
13
1994
215
221
18
Raskind
 
WH
Tirumali
 
N
Jacobson
 
R
Singer
 
J
Fialkow
 
PJ
Evidence for a multistep pathogenesis of a myelodysplastic syndrome.
Blood.
63
1984
1318
1323
19
Lawrence
 
HJ
Broudy
 
VC
Magenis
 
RE
et al
Cytogenetic evidence for involvement of B lymphocytes in acquired idiopathic sideroblastic anemias.
Blood.
70
1987
1003
1005
20
Tefferi
 
A
Thibodeau
 
SN
Solberg
 
LA
Clonal studies in the myelodysplastic syndrome using X-linked restriction fragment length polymorphisms.
Blood.
75
1990
1770
1773
21
Culligan
 
DJ
Cachia
 
P
Whittaker
 
J
Jacobs
 
A
Padua
 
RA
Clonal lymphocytes are detectable in only some cases of MDS.
Br J Haematol.
81
1992
346
352
22
White
 
NJ
Nacheva
 
E
Asimakopoulos
 
FA
Bloxham
 
D
Paul
 
B
Green
 
AR
Deletion of chromosome 20q in myelodysplasia can occur in a multipotent precursor of both myeloid cells and B cells.
Blood.
83
1994
2809
2816
23
Swolin
 
B
Weinfeld
 
A
Ridell
 
B
Waldenstrom
 
J
Westin
 
J
On the 5q− deletion: clinical and cytogenetic observations in ten patients and review of the literature.
Blood.
58
1981
986
993
24
Abrahamson
 
G
Boultwood
 
J
Madden
 
J
et al
Clonality of cell populations in refractory anaemia using combined approach of gene loss and X-linked restriction fragment length polymorphism-methylation analyses.
Br J Haematol.
79
1991
550
555
25
Gerritsen
 
WR
Donohue
 
J
Bauman
 
J
et al
Clonal analysis of myelodysplastic syndrome: monosomy 7 is expressed in the myeloid lineage, but not in the lymphoid lineage as detected by fluorescent in situ hybridization.
Blood.
80
1992
217
224
26
van Kamp
 
H
Fibbe
 
WE
Jansen
 
RP
et al
Clonal involvement of granulocytes and monocytes, but not of T and B lymphocytes and natural killer cells in patients with myelodysplasia: analysis by X-linked restriction fragment length polymorphisms and polymerase chain reaction of the phosphoglycerate kinase gene.
Blood.
80
1992
1774
1780
27
Nylund
 
SJ
Verbeek
 
W
Larramendy
 
ML
et al
Cell lineage involvement in four patients with myelodysplastic syndrome and t(1;7) or trisomy 8 studied by simultaneous immunophenotyping and fluorescence in situ hybridization.
Cancer Genet Cytogenet.
70
1993
120
124
28
Kroef
 
MJ
Fibbe
 
WE
Mout
 
R
et al
Myeloid but not lymphoid cells carry the 5q deletion: polymerase chain reaction analysis of loss of heterozygosity using mini-repeat sequences on highly purified cell fractions.
Blood.
81
1993
1849
1854
29
van Lom
 
K
Hagemeijer
 
A
Smit
 
EM
Lowenberg
 
B
In situ hybridization on May-Grunwald Giemsa-stained bone marrow and blood smears of patients with hematologic disorders allows detection of cell-lineage-specific cytogenetic abnormalities.
Blood.
82
1993
884
888
30
Han
 
K
Lee
 
W
Harris
 
CP
Kim
 
W
Shim
 
S
Meisner
 
LF
Quantifying chromosome changes and lineage involvement in myelodysplastic syndrome (MDS) using fluorescent in situ hybridization (FISH).
Leukemia.
8
1994
81
86
31
Soenen
 
V
Fenaux
 
P
Flactif
 
M
et al
Combined immunophenotyping and in situ hybridization (FICTION): a rapid method to study cell lineage involvement in myelodysplastic syndromes.
Br J Haematol.
90
1995
701
706
32
Abruzzese
 
E
Buss
 
D
Rainer
 
R
Rao
 
PN
Pettenati
 
MJ
Study of clonality in myelodysplastic syndromes: detection of trisomy 8 in bone marrow cell smears by fluorescence in situ hybridization.
Leuk Res.
20
1996
551
557
33
van Lom
 
K
Hagemeijer
 
A
Vandekerckhove
 
F
Smit
 
EM
Lowenberg
 
B
Cytogenetic clonality analysis: typical patterns in myelodysplastic syndrome and acute myeloid leukaemia.
Br J Haematol.
93
1996
594
600
34
Bernell
 
P
Jacobsson
 
B
Nordgren
 
A
Hast
 
R
Clonal cell lineage involvement in myelodysplastic syndromes studied by fluorescence in situ hybridization and morphology.
Leukemia.
10
1996
662
668
35
Kroef
 
MJ
Bolk
 
MJ
Muus
 
P
et al
Mosaicism of the 5q deletion as assessed by interphase FISH is a common phenomenon in MDS and restricted to myeloid cells.
Leukemia.
11
1997
519
523
36
Faderl
 
S
Talpaz
 
M
Estrov
 
Z
O'Brien
 
S
Kurzrock
 
R
Kantarjian
 
HM
The biology of chronic myeloid leukemia.
N Engl J Med.
341
1999
164
172
37
Van den Berghe
 
H
Cassiman
 
JJ
David
 
G
Fryns
 
JP
Michaux
 
JL
Sokal
 
G
Distinct haematological disorder with deletion of long arm of no. 5 chromosome.
Nature.
251
1974
437
438
38
Van den Berghe
 
H
Vermaelen
 
K
Mecucci
 
C
Barbieri
 
D
Tricot
 
G
The 5q-anomaly.
Cancer Genet Cytogenet.
17
1985
189
255
39
Boultwood
 
J
Lewis
 
S
Wainscoat
 
JS
The 5q-syndrome.
Blood.
84
1994
3253
3260
40
Van den Berghe
 
H
Michaux
 
L
5q−, twenty-five years later: a synopsis.
Cancer Genet Cytogenet.
94
1997
1
7
41
Greenberg
 
P
Cox
 
C
LeBeau
 
MM
et al
International scoring system for evaluating prognosis in myelodysplastic syndromes.
Blood.
89
1997
2079
2088
42
De Witte
 
T
Van Biezen
 
A
Hermans
 
J
et al
Autologous bone marrow transplantation for patients with myelodysplastic syndrome (MDS) or acute myeloid leukemia following MDS: chronic and Acute Leukemia Working Parties of the European Group for Blood and Marrow Transplantation.
Blood.
90
1997
3853
3857
43
Terstappen
 
LW
Huang
 
S
Safford
 
M
Lansdorp
 
PM
Loken
 
MR
Sequential generations of hematopoietic colonies derived from single nonlineage-committed CD34+CD38− progenitor cells.
Blood.
77
1991
1218
1227
44
Hao
 
QL
Thiemann
 
FT
Petersen
 
D
Smogorzewska
 
EM
Crooks
 
GM
Extended long-term culture reveals a highly quiescent and primitive human hematopoietic progenitor population.
Blood.
88
1996
3306
3313
45
Larochelle
 
A
Vormoor
 
J
Hanenberg
 
H
et al
Identification of primitive human hematopoietic cells capable of repopulating NOD/SCID mouse bone marrow: implications for gene therapy.
Nat Med.
2
1996
1329
1337
46
Bonnet
 
D
Dick
 
JE
Human acute myeloid leukemia is organized as a hierarchy that originates from a primitive hematopoietic cell.
Nat Med.
3
1997
730
737
47
Bennett
 
JM
Catovsky
 
D
Daniel
 
MT
et al
Proposals for the classification of the myelodysplastic syndromes.
Br J Haematol.
51
1982
189
199
48
Ramsfjell
 
V
Bryder
 
D
Bjorgvinsdottir
 
H
et al
Distinct requirements for optimal growth and in vitro expansion of human CD34(+)CD38(−) bone marrow long-term culture-initiating cells (LTC-IC), extended LTC-IC, and murine in vivo long-term reconstituting stem cells.
Blood.
94
1999
4093
4102
49
Jacobsson
 
B
Bernell
 
P
Arvidsson
 
I
Hast
 
R
Classical morphology, esterase cytochemistry, and interphase cytogenetics of peripheral blood and bone marrow smears.
J Histochem Cytochem.
44
1996
1303
1309
50
Borge
 
OJ
Ramsfjell
 
V
Cui
 
L
Jacobsen
 
SE
Ability of early acting cytokines to directly promote survival and suppress apoptosis of human primitive CD34+CD38− bone marrow cells with multilineage potential at the single-cell level: key role of thrombopoietin.
Blood.
90
1997
2282
2292
51
Sutherland
 
HJ
Lansdorp
 
PM
Henkelman
 
DH
Eaves
 
AC
Eaves
 
CJ
Functional characterization of individual human hematopoietic stem cells cultured at limiting dilution on supportive marrow stromal layers.
Proc Natl Acad Sci U S A.
87
1990
3584
3588
52
Cashman
 
JD
Lapidot
 
T
Wang
 
JC
et al
Kinetic evidence of the regeneration of multilineage hematopoiesis from primitive cells in normal human bone marrow transplanted into immunodeficient mice.
Blood.
89
1997
4307
4316
53
Ogawa
 
M
Differentiation and proliferation of hematopoietic stem cells.
Blood.
81
1993
2844
2853
54
Eaves
 
C
Myelopoiesis.
Leukemia.
Henderson
 
ES
Lister
 
TA
Greaves
 
MF
1996
46
64
WB Saunders
Philadelphia, Pa
55
Dick
 
JE
Normal and leukemic human stem cells assayed in SCID mice.
Semin Immunol.
8
1996
197
206
56
Zanjani
 
ED
Almeida-Porada
 
G
Flake
 
AW
The human/sheep xenograft model: a large animal model of human hematopoiesis.
Int J Hematol.
63
1996
179
192
57
Domen
 
J
Weissman
 
IL
Self-renewal, differentiation or death: regulation and manipulation of hematopoietic stem cell fate.
Mol Med Today.
5
1999
201
208
58
Ramsfjell
 
V
Borge
 
OJ
Cui
 
L
Jacobsen
 
SE
Thrombopoietin directly and potently stimulates multilineage growth and progenitor cell expansion from primitive (CD34+ CD38−) human bone marrow progenitor cells: distinct and key interactions with the ligands for c-kit and flt3, and inhibitory effects of TGF-beta and TNF-alpha.
J Immunol.
158
1997
5169
5177
59
Nevill
 
TJ
Fung
 
HC
Shepherd
 
JD
et al
Cytogenetic abnormalities in primary myelodysplastic syndrome are highly predictive of outcome after allogeneic bone marrow transplantation.
Blood.
92
1998
1910
1917
60
Mehrotra
 
B
George
 
TI
Kavanau
 
K
et al
Cytogenetically aberrant cells in the stem cell compartment (CD34+lin−) in acute myeloid leukemia.
Blood.
86
1995
1139
1147
61
Haase
 
D
Feuring-Buske
 
M
Konemann
 
S
et al
Evidence for malignant transformation in acute myeloid leukemia at the level of early hematopoietic stem cells by cytogenetic analysis of CD34+ subpopulations.
Blood.
86
1995
2906
2912
62
Saitoh
 
K
Miura
 
I
Takahashi
 
N
Miura
 
AB
Fluorescence in situ hybridization of progenitor cells obtained by fluorescence-activated cell sorting for the detection of cells affected by chromosome abnormality trisomy 8 in patients with myelodysplastic syndromes.
Blood.
92
1998
2886
2892
63
Baum
 
CM
Weissman
 
IL
Tsukamoto
 
AS
Buckle
 
AM
Peault
 
B
Isolation of a candidate human hematopoietic stem-cell population.
Proc Natl Acad Sci U S A.
89
1992
2804
2808
64
Galy
 
A
Travis
 
M
Cen
 
D
Chen
 
B
Human T, B, natural killer, and dendritic cells arise from a common bone marrow progenitor cell subset.
Immunity.
3
1995
459
473
65
Kondo
 
M
Weissman
 
IL
Akashi
 
K
Identification of clonogenic common lymphoid progenitors in mouse bone marrow.
Cell.
91
1997
661
672
66
Buckton
 
KE
Brown
 
WM
Smith
 
PG
Lymphocyte survival in men treated with x-rays for ankylosing spondylitis.
Nature.
214
1967
470
473
67
Takahashi
 
N
Miura
 
I
Saitoh
 
K
Miura
 
AB
Lineage involvement of stem cells bearing the Philadelphia chromosome in chronic myeloid leukemia in the chronic phase as shown by a combination of fluorescence-activated cell sorting and fluorescence in situ hybridization.
Blood.
92
1998
4758
4763

Author notes

Sten E. W. Jacobsen, Stem Cell Laboratory, Institute of Laboratory Medicine, University Hospital of Lund, 22185, Lund, Sweden; e-mail: sten.jacobsen@molmed.lu.se.

Sign in via your Institution