Phenotypic and functional characterization of long-term culture- initiating cells present in peripheral blood progenitor collections of normal donors treated with granulocyte colony-stimulating factor

Granulocyte colony-stimulating factor (G-CSF) mobilized peripheral blood progenitor cells (PBPC) have successfully been used as stem cells for both autologous and allogeneic transplants. However, little is known concerning the absolute number and phenotype of primitive progenitors, such as long-term culture-initiating cells (LTC-IC) in mobilized PBPC. The aim of our study was to evaluate the capacity of G- CSF to mobilize LTC-IC in the PB of normal individuals and to evaluate the phenotypic and functional characteristics of G-CSF mobilized LTC- IC. G-CSF was administered to 29 healthy volunteers at 7.5 micrograms or 10 micrograms/kg/d subcutaneously (SC) for 5 consecutive days and PBPC were harvested on day 6. Mobilization with G-CSF increased the absolute number of week 5 LTC-IC in PB 60-fold, while the number of CD34+ cells and committed colony forming cells (CFC) was increased sevenfold to 12-fold. The frequency of CFC and week 5 LTC-IC in CD34+ cells selected by fluorescence-activated cell sorter (FACS) from mobilized PBPC was 2 +/- 0.3-fold and 9 +/- 2.2-fold higher respectively than in CD34+ cells selected from unmobilized PBMNC. CFC were enriched in the CD34+ CD38+ and CD34+ HLA-DR+ populations. The absolute number of LTC-IC present in CD34+ CD38- and CD34+ HLA-DR- cells selected by FACS from either mobilized PBPC, unmobilized PBMNC or steady state bone marrow (BM) was similar (0.5% to 2%). In contrast to unmobilized PBMNC or steady state BM CD34+ CD38+ and CD34+ HLA-DR+ cells, which contain less than 0.1% LTC-IC, CD34+ CD38+ and CD34+ HLA- DR+ cells sorted from mobilized PBPC contained 0.5% to 5% of cells capable of sustaining hematopoiesis in long-term cultures for 5 weeks. However, 90% to 95% of LTC-IC present in mobilized CD34+ CD38+ and CD34+ HLA-DR+ cells were not able to sustain hematopoiesis for 8 weeks, while 30% of CD34+ CD38- and CD34+ HLA-DR- LTC-IC present in mobilized PBPC could sustain hematopoiesis for at least 8 weeks. This suggests that the majority of CD34+ CD38+ and CD34+ HLA-DR+ week 5 LTC-IC represent progenitors at an intermediate state of differentiation. We conclude that G-CSF effectively mobilizes LTC-IC in the blood of normal individuals. Although a fraction of these cells has functional characteristics similar to those of steady state PBMNC or BM LTC-IC, more than 85% of mobilized PBPC LTC-IC are CD34+ CD38+ and CD34+ HLA- DR+, capable of sustaining hematopoiesis for 5 weeks, but not for 8 weeks. The functional and phenotypic characterization of primitive and more mature populations of LTC-IC in mobilized PBPC should prove extremely useful in future studies examining the role of these progenitors in engraftment following transplantation.     

Normal primitive haemopoietic progenitors are more frequent than their leukaemic counterpart in newly diagnosed patients with chronic myeloid leukaemia but rapidly decline with time

We carried out studies to quantify Ph-negative progenitors both in steady state and during regeneration after chemotherapy and G-CSF in 23 newly diagnosed chronic myeloid leukaemia (CML) patients (group A) and in 14 individuals more than a year from diagnosis (nine in chronic and five in accelerated phase, group B). In steady-state bone marrow, Ph-negative long-term culture initiating cells (LTC-IC) and Ph-negative colony-forming-cells (CFC) were detected in 18/23 and 14/23 patients of group A versus 3/14 and 3/14 patients of group B (P<0.001 and P<0.02, respectively). The absolute number of mobilized Ph-negative progenitors was markedly higher in group A versus group B (P<0.02 for LTC-IC, P<0.003 for CFC). 12/16 newly diagnosed patients mobilized Ph-negative LTC-IC only and the yield was in the range of normal allogeneic donors. Overall the frequency of Ph-negative LTC-IC in the bone marrow predicted the yield of Ph-negative LTC-IC mobilized into peripheral blood (P<0.001). The bone marrow frequency of Ph-positive LTC-IC was considerably lower than the normal counterpart. Taken together, these findings suggest that normal progenitors are relatively well preserved in newly diagnosed CML patients, but tend to rapidly decline with time. This observation helps in the understanding of the pathogenesis of CML and has potential implications for autografting. The optimal time for a successful collection of Ph-negative circulating progenitors would appear to be soon after diagnosis.     

Frequency and differentiation capacity of circulating LTC-IC mobilized by G-CSF or GM-CSF following chemotherapy: a comparison with steady-state bone marrow and peripheral blood

OBJECTIVE: The present study was designed to compare directly the frequency of circulating LTC-IC and E-LTC-IC mobilized in peripheral blood (PB) after chemotherapy supported by either G-CSF (PB-G) or GM-CSF (PB-GM) in comparison to steady-state bone marrow (BM) and PB (PB-ST) values in the same patients. MATERIALS AND METHODS: Long-term cultures (LTC) were performed from 20 patients with malignant lymphoma at saturating cell concentrations to assess bulk progenitor cell production and by limiting dilution assay (LDA) to measure both frequency of LTC-IC and their proliferative and differentiation capacities. RESULTS: While CFC production in bulk LTC was higher at weeks 3-5 with PB-G than with PB-GM samples, week-5 LTC-IC and week-10 LTC-IC (E-LTC-IC) frequencies were not different using a LDA. However, the number of CFC derived from a single LTC-IC was higher in PB-G patients than in PB-GM patients (p = 0.01). Interestingly, the frequency of LTC-IC per 1 x 10(5) MNC in mobilized PB positively correlated with one-year marrow progenitor cell recovery, in contrast to the number of autografted CD34(+) cells and CFU-GM per kg. CONCLUSION: Both G-CSF and GM-CSF resulted in similar increases in LTC-IC and E-LTC-IC in PB at comparable levels to those present in BM. However, the differentiation capacity of LTC-IC was higher after mobilization with G-CSF than with GM-CSF, suggesting qualitative differences in LTC-IC mobilized with these growth factors.     

Age- and irradiation-associated loss of bone marrow hematopoietic function in mice is reversed by recombinant human growth hormone

OBJECTIVE: The aim of this story was to evaluate the activity of recombinant human (rh) growth hormone (GH) in restoring bone marrow progenitor cell growth as well as cytokine-elicited stem cell mobilization in aged BALB/c mice with impaired marrow hematopoietic function and reduced stem cell mobilizing capacity. MATERIALS AND METHODS: BALB/c mice included in this study were either naturally aged (group I) or aged after having been used for radioprotective assays (group II). Mice were treated for 5 weeks with either rhGH [2.5 mg/kg/day intraperitoneally (IP)] or phosphate-buffered saline (PBS). Subsequently, colony-forming cells (CFCs) and long-term culture-initiating cells (LTC-ICs) were evaluated. In addition, progenitor cell mobilization elicited by granulocyte colony-stimulating factor (rhG-CSF) was analyzed. RESULTS: Compared with young controls, the growth of marrow CFCs and LTC-ICs was significantly reduced (P < or = 0.05) in group I and II mice. Treatment with rhGH significantly enhanced marrow hematopoiesis in mice of both groups, as demonstrated by a complete restoration of marrow cellularity, and CFC and LTC-IC growth. To further evaluate the hematopoietic potential of rhGH, aged mice treated with rhGH or PBS were mobilized with rhG-CSF (10 microg/day IP for 5 days). Compared with PBS-injected mice, rhGH-treated mice showed a significant improvement of rhG/CSF-elicited stem cell mobilization, with significant increases of white blood cell counts (5633 vs 8133, P < or = 0.05), frequency of circulating CFCs per 10(5) mononuclear cells (36 vs 67, P < or = 0.009), as well as absolute numbers per mL of blood of circulating CFCs (783 vs 2288, P < or = 0.001) and LTC-IC (21 vs 64, P < or = 0.001). CONCLUSION: Our data demonstrate in mice that a 5-week treatment with rhGH restores age- and irradiation-associated loss of marrow primitive and committed progenitors.     

Plastic-adherent progenitor cells in mobilized peripheral blood progenitor cell collections

The use of peripheral blood progenitor cells (PBPC) to reconstitute hematopoiesis after high-dose chemoradiotherapy is now commonplace in the treatment of malignancies. Attempts to characterize these cells have concentrated primarily on their phenotype and their content of clonogenic colony-forming cells (CFC). We have used a plastic-adherent delta (P delta) assay system to evaluate the quantity and quality of more primitive cells in addition to the conventional measurements of CFC and CD34-positive cells. The leukapheresis products from 20 patients mobilized using cyclophosphamide (Cy) and granulocyte colony- stimulating factor (G-CSF) were examined for progenitor cell content. The mean number of mononuclear cells (MNC), colony-forming units- granulocyte/macrophage (CFU-GM), and CD34-positive cells from two leukaphereses per patients were 7.9 x 10(8)/kg, 47.3 x 10(4)/kg, and 10.5 x 10(6)/kg, respectively. The mean number of P delta progenitors was 9.3 x 10(4)/kg. Limiting dilution analyses showed the frequency of P delta progenitors in PBPC to be between 1 and 5.3 per 10(5) MNC and that each P delta progenitor has the proliferative capability to generate an overall mean of 4.5 CFU-GM. Of the 20 patients, 16 underwent autografting with PBPC alone. Fifteen patients engrafted neutrophils and platelets within 16 days. One patient had delayed engraftment associated with inadequate etoposide clearance. Statistical analysis showed a strong correlation between numbers of CFU-GM and CD34 positivity. The numbers of plastic-adherent P delta progenitor cells did not correlate with CFU-GM or CD34-positive cells. We conclude that the plastic-adherent P delta progenitor cell assay is capable of measuring primitive hematopoietic cells and that it may be useful for the investigation of primitive progenitors in PBPC harvests.     

Chronic myelogenous leukemia primitive hematopoietic progenitors demonstrate increased sensitivity to growth factor-induced proliferation and maturation

We investigated whether primary chronic myelogenous leukemia (CML) hematopoietic progenitors demonstrated altered proliferation and maturation in response to growth factor (GF) stimulation.The effect of GF stimulation on proliferation and expansion of committed and primitive progenitors (colony forming cells [CFC]) was evaluated. Culture of CML and normal CD34(+) cells with different GF for 7 days resulted in similar expansion of committed progenitors (CFC). In contrast, GF culture conditions that expanded normal primitive progenitors (week-6 long-term culture-initiating cells (LTC-IC)] led to depletion of CML LTC-IC numbers. GF culture also resulted in increased depletion of week-10 extended LTC-IC, which represent an even more primitive progenitor population, from CML compared with normal CD34(+) cells. CML CD34(+) cells enter into cycle more quickly than normal CD34(+) cells and CML CFC expansion was accelerated compared to normal CFC. Evaluation of primitive progenitor proliferation using PKH-26 and single-cell LTC-IC analysis demonstrated that the majority of CML LTC-IC remaining after GF culture originated from divided CD34(+) cells, whereas GF-cultured normal LTC-IC were derived mainly from undivided cells. Depletion of CML primitive progenitor numbers in association with increased proliferation suggests increased sensitivity to GF-induced maturation.These studies indicate that CML primitive progenitors have enhanced sensitivity to GF-induced cell division and maturation. Altered GF responsiveness may contribute to abnormal expansion of malignant myeloid cells in CML. These findings may also be applied toward the development of novel approaches to select benign stem cells in CML.     

Long-lasting decrease of marrow and circulating long-term culture initiating cells after allogeneic bone marrow transplant.

We investigated bone marrow (BM) and circulating (PB) hematopoietic progenitor cells in 37 normal donors and in 25 patients 1 to 8 years after successful allogeneic bone marrow transplant. At the time of testing, transplanted patients had normal blood counts and bone marrow cellularity. By flow cytometry, BM CD34+ cells were found to be three- to four-fold decreased in transplanted patients compared to normal donors, while the number of PB CD34+ cells was the same as in normal donors. Using a methylcellulose colony assay, primary BM colony-forming cells (CFU-GM) were decreased 2.1-fold, whereas PB CFU-GM were only marginally decreased. In a long-term culture initiating cell (LTC-IC) assay, an eight-fold decrease of early progenitor cells was observed in the marrow of transplanted patients compared to normal donors, and a five-fold decrease was documented in peripheral blood. We found that the BM LTC-IC cell number correlated with concurrently determined BM CD34+ cells and committed progenitor cell number (measured as CFU-GM) and with PB LTC-IC number, but not with PB CFU-GM and CD34+ cells. We conclude that marrow and circulating early stem cell compartments, as measured by the LTC-IC assay, are greatly and permanently depressed following bone marrow transplant. The correlation between BM and PB LTC-IC indicates that the enumeration of circulating LTC-IC can be used as a measure of the stem cell compartment in the bone marrow after transplant. It seems that the deficiency of the most immature progenitor cells persists forever after successful bone marrow transplant; this means that a complete hematopoietic reconstitution can be sustained by a reduced stem cell pool.     

Comparison of megakaryopoiesis in vitro of paired peripheral blood progenitor cells and bone marrow harvested during remission in patients with acute myeloid leukaemia

We have studied paired peripheral blood progenitor cells (PBPC) and bone marrow (BM) samples from 12 acute myeloid leukaemia (AML) patients following intensive chemotherapy, and assessed direct granulocyte-macrophage colony-forming units (CFU-GM), erythroid burst-forming units (BFU-E), megakaryocyte CFU (CFU-Mk) numbers and the production of CD61+ (platelet glycoprotein IIIa) cells in suspension culture in response to various haemopoietic growth factor combinations. We found that CFU-GM and BFU-E numbers per 105 mononuclear cells were similar in both AML PBPC and BM harvests; CFU-Mk numbers, however, were significantly higher in PBPC than BM. In addition, the higher total white cell count of the PBPC harvests meant that PBPC have much higher numbers of total progenitors per collection. CD61+ cell numbers in suspension cultures of AML PBPC and BM were lower than those of harvested normal marrow. However, response to pegylated recombinant human megakaryocyte growth and development factor (PEGrHuMGDF) both alone and in combination with other growth factors was qualitatively similar to that of normal BM. As with normal BM, response to PEGrHuMGDF alone did not increase further with addition of granulocyte colony-stimulating factor (G-CSF), granulocyte-macrophage CSF (GM-CSF), interleukin 6 (IL-6) or erythropoietin (EPO) in the AML PBPC and BM. Further responses over PEGrHuMGDF alone were seen when added with stem cell factor (SCF) or with a combination of SCF + IL-3 + EPO in both AML PBPC and BM cultures; however, the magnitude of the response was greater in the PBPC cultures. Response to PEGrHuMGDF + IL-3 was seen in the PBPC cultures but not in the AML BM. These data suggest that, in AML patients, there are proportionally more megakaryocyte progenitor cells in the mobilized PBPC than in the BM harvests, which would explain the more rapid platelet recovery following PBPC autografts.     

Both cycling and noncycling primitive progenitors continue to be mobilized into the circulation during the leukapheresis of patients pretreated with chemotherapy and G-CSF

Colony-forming cells (CFC) and long-term culture-initiating cells (LTC-IC) include a spectrum of progenitor types whose potential contributions to the haemopoietic recovery seen in patients transplanted with mobilized peripheral blood progenitor cells (PBPC) remains unclear. We evaluated both the number and cycling status of the circulating LTC-IC and CFC harvested from 12 patients treated with chemotherapy and G-CSF using a modified 6-week LTC-IC assay. The frequency of the LTC-IC and CFC in the mobilized PB samples were increased 45- and 750-fold, respectively. Interestingly, comparison of these values for PB samples, taken just prior to the start of the leukapheresis, with the progenitor content of the 3 h harvest, showed that, on average, the leukapheresis product contained 19 times more LTC-IC ( P  < 0.01) than had been detectable in the entire blood volume of the patients at the start of the collection, whereas the number of CFC collected was approximately the same as the number in the initial circulating pool of PBPC. Cycling studies showed many of the LTC-IC in the apheresis collections to be proliferating although not more so than in the steady-state marrow LTC-IC compartment (i.e. per cent kill of mobilized LTC-IC after 16 h in ³H-Tdr = 70 ± 8%, n  = 9). On the other hand, the majority of the CFC in the apheresis collections were initially quiescent (per cent kill after 16 h in ³H-Tdr = 37 ± 6%, n  = 12). These findings demonstrate the rapidity with which a primitive subset of LTC-IC may enter the circulation during the early phase of rebound haemopoiesis induced by chemotherapy plus G-CSF and provide evidence of differences in the mechanisms regulating LTC-IC and CFC mobilization.     

Evaluation of optimal survival of primitive progenitor cells (LTC-IC) from PBPC apheresis products after overnight storage

Optimal overnight (ON) storage of PBPC aphereses is becoming an increasingly important issue and different options for storing PBPC products exist. The survival of primitive progenitor cells is of major interest, as recent data suggest that these progenitors are not only important for long-term engraftment but also contribute significantly to the early phase of hematopoietic engraftment after myeloablative therapy. We therefore investigated the survival of primitive progenitor cells (ie long-term culture initiating cells, LTC-IC) before (ie within 2 h after finishing the apheresis procedure) and after ON storage lasting 16 to 20 h. In addition, we compared the % of recovery of LTC-IC with that of mature progenitors (ie colony-forming cells, CFC) and with the % viability of the mononuclear cells in the apheresis product. Aliquots of PBPC aphereses products were tested in collection bags at room temperature (RT), in EDTA tubes both at RT or 4 degrees C +/- the addition of autologous plasma (AP; 2.6-fold the apheresis volume) and +/- the possibility of gas exchange. Mean viable cell counts did not show strong differences between the different storage conditions and were poor predictors for the survival of CFC and LTC-IC. At RT (collection bags, EDTA tubes +/- gas exchange) recoveries (% of input) of both, CFC (18%, 18% and 31%) and LTC-IC (10%, 4%, 17%) were low. The addition of AP at RT improved the survival of CFC and LTC-IC to 66% and 38%, respectively. Optimal recoveries for both types of progenitors (CFC: 99%, LTC-IC: 109%) were obtained at 4 degrees C in the presence of AP. In addition, a good correlation between the survival of CFC and LTC-IC was obtained (r = 0.76) suggesting that the analysis of CFC may also allow some conclusions to be drawn on the survival of LTC-IC. Bone Marrow Transplantation (2000) 25, 197-200.     

Autografting with Ph-negative progenitors in patients at diagnosis of chronic myeloid leukemia induces a prolonged prevalence of Ph-negative hemopoiesis

OBJECTIVE: In many patients with chronic myeloid leukemia (CML), a residual population of primitive normal (Ph-negative) progenitors persists despite the marked expansion of the leukemic (Ph-positive) clone. These cells may be found in the blood of patients studied soon after diagnosis or during the period of endogenous hematopoietic recovery that follows myeloreductive therapy. Based on those observations, we have developed a clinical protocol that allows collection of Ph-negative peripheral blood progenitor cells (PBPC) with transplantable hematopoietic regenerative potential. The aim of this study is to examine changes that occur in the percentage of Ph-negative- and Ph-positive-committed progenitor cells and to determine the relationship between changes and clinical outcome. MATERIALS AND METHODS: We followed 15 patients with CML, mobilized and autografted soon after diagnosis with 85%-100% Ph-negative PBPC for a median time of 28 months (range 18-50) after transplant. At 6 months, 1 year, 2 years, and last follow-up, cytogenetic analyses were performed on fresh bone marrow cells and on colony-forming cells (CFC). RESULTS: Autologous transplantation induces a reduction in the proportion of Ph-positive CFC, from 70%-100% to 0%-25% in the majority of patients (78%). After autografting, 8 of 15 patients achieved a long-lasting cytogenetic remission (median, 24 months; range, 21-43) with a Ph-positivity ranging between 0% and 20% at the level of mature mononuclear cells and colony-forming cells (CFC). In some patients, the majority of CFC remained Ph-negative, whereas the majority of the mature cells were Ph-positive. Other patients (5/15) developed cytogenetic relapse (100% Ph-positive), although they were in hematological remission. We found that detection of Ph-positive long-term-culture initiating cells (LTC-IC) in the marrow at diagnosis was the only factor significantly associated with recurrence of the disease (p < 0.01); on the other hand, the number of Ph-negative LTC-IC infused showed a significant correlation with a better outcome (p < 0.03). CONCLUSION: We have shown that a prolonged period of complete or almost complete Ph-negative hemopoiesis can be achieved in patients with CML who undergo autografting with Ph-negative progenitors. Longer follow-up study will be needed to assess whether these changes are associated with improved survival.     

Peripheral blood progenitor cells mobilized by recombinant human granulocyte colony-stimulating factor plus recombinant rat stem cell factor contain long-term engrafting cells capable of cellular proliferation for more than two years as shown by serial transplantation in mice

Mobilized peripheral blood progenitor cells (PBPC) have been shown to provide rapid engraftment in patients given high-dose chemotherapy. PBPC contain cells with long-term engraftment potential as shown in animal models. In this study we have further analyzed mobilized PBPC for their ability to support serial transplantation of irradiated mice. Transplantation of recombinant human granulocyte colony-stimulating factor (rhG-CSF) plus recombinant rat stem cell factor (rrSCF) mobilized PBPC resulted in 98% donor engraftment of primary recipients at 12 to 14 months post-transplantation. Bone marrow (BM) cells from these primary recipients were harvested and transplanted into secondary recipients. At 6 months posttransplantation, all surviving secondary recipients had donor engraftment. Polymerase chain reaction (PCR) analysis showed greater than 90% male cells in spleens, thymuses, and lymph nodes. Myeloid colonies from BM cells of secondary recipients demonstrated granulocyte/macrophage colony-forming cells (GM-CFC) of male origin in all animals. In comparison, transplantation of rhG-CSF mobilized PBPC resulted in decreased male engraftment in secondary recipients. BM cells from secondary recipients, who originally received PBPC mobilized by the combination of rrSCF and rhG-CSF, were further passaged to tertiary female recipients. At 6 months posttransplantation, 90% of animals had male-derived hematopoiesis by whole-blood PCR analysis. These data showed that PBPC mobilized with rhG-CSF plus rrSCF contained cells that are transplantable and able to maintain hematopoiesis for more than 26 months, suggesting that the mobilized long-term reconstituting stem cells (LTRC) have extensive proliferative potential and resemble those that reside in the BM. In addition, the data demonstrated increased mobilization of LTRC with rhG- CSF plus rrSCF compared to rhG-CSF alone.     

Primitive hematopoietic progenitors within mobilized blood are spared by uncontrolled rate freezing

Uncontrolled-rate freezing techniques represent an attractive alternative to controlled-rate cryopreservation procedures which are time-consuming and require high-level technical expertise. In this study, we report our experience using uncontrolled-rate cryopreservation and mechanical freezer storage at -140 degrees C. Twenty-eight PBPC samples (10 cryovials, 18 freezing bags) from 23 patients were cryopreserved in a cryoprotectant solution composed of phosphate-buffered saline (80%, v/v) supplemented with human serum albumin (10%, v/v) and dimethylsulfoxide (10%, v/v). The cryopreservation procedure required on average 1.5 h. The mean (+/- s.e.m.) storage time of cryovials and bags was 344+/-40 and 299+57 days, respectively. Although cell thawing was associated with a statistically significant reduction of the absolute number of nucleated cells (vials: 0.3x10(9) vs. 0.2x10(9), P< or =0.02; bags: 14x10(9) vs. 11x10(9), P< or =0.0003), the growth of committed progenitors was substantially unaffected by the freezing-thawing procedure, with mean recoveries of CFU-Mix, BFU-E, and CFU-GM ranging from 60+/- 29% to 134+/-15%. Mean recoveries of LTC-IC from cryovials and bags were 262+/-101% and 155+/-27% (P< or =0.2), respectively. In 14 out of 23 patients who underwent high-dose chemotherapy and PBPC reinfusion, the pre-and post-freezing absolute numbers of hematopoietic progenitors cryopreserved in bags were compared. A significant reduction was detected for CFU-Mix (11 vs. 7.4x10(5)), but no significant loss of BFU-E (180 vs. 150x10(5)), CFU-GM (400 vs. 290x10(5)) and LTC-IC (15 vs. 16x10(5)) could be demonstrated. When these patients were reinfused with uncontrolled-rate cryopreserved PBPC, the mean number of days to reach 1x10(9)/l white blood cells and 50x10(9)/l platelets were 9 and 13, respectively. In conclusion, the procedure described here is characterized by short execution time, allows a substantial recovery of primitive and committed progenitors and is associated with prompt hematopoietic recovery following myeloablative therapy even after long-term storage.     

Biological properties of peripheral blood progenitor cells mobilized by cyclophosphamide and granulocyte colony-stimulating factor

Patients transplanted with mobilized blood progenitor cells (PBPC) recover their neutrophil counts more rapidly than patients transplanted with bone marrow even when they receive the same dose/kg of granulocyte-macrophage colony-forming cells (CFU-GM). Here we have sought a biological explanation for this phenomenon. Most CD34-positive PBPC are quiescent (<1% in S phase) when they are collected from the bloodstream of patients treated with cyclophosphamide and granulocyte colony-stimulating factor (G-CSF), but we have shown that they are able to resume proliferation rapidly in vitro by measuring the kinetics of CFU-GM production by primitive plastic-adherent (PΔ) cells. Also, PΔcells in PBPC harvests, unlike normal marrow PΔ cells, were insensitive to cell-cycle restraint imposed by contact with marrow-derived stromal cells. We found that PΔ cells in PBPC collections produce relatively more CFU-GM and relatively fewer BFU-E than PΔ cells in bone marrow, indicating that granulopoiesis might occur at the expense of erythropoiesis, but we were unable to find any differences in the kinetics of granulocytic maturation between PBPC and bone marrow. Our interpretation of these findings is that transplanted PBPC rapidly enter the cell cycle and contact with stromal cells in the marrow does not reduce the proportion of progenitors participating in neutrophil production. Consequently, neutrophil recovery after PBPC infusion is more rapid than neutrophil recovery after marrow infusion. Granulopoiesis at the expense of erythropoiesis may also contribute to this effect.     

Enhanced detection, maintenance, and differentiation of primitive human hematopoietic cells in cultures containing murine fibroblasts engineered to produce human steel factor, interleukin-3, and granulocyte colony-stimulating factor

To determine whether the sensitivity of the human long-term culture- initiating cell (LTC-IC) assay could be increased, we have evaluated a spectrum of different fibroblast cell lines for their abilities to influence the number of cells detectable as LTC-IC, to influence LTC-IC maintenance, and/or to influence LTC-IC differentiation into colony- forming cells (CFC) in cocultures containing various sources of LTC-IC. In a series of initial experiments with highly purified subpopulations of CD34+ cells from normal human marrow, no significant difference could be found between any of 3 different murine stromal fibroblast cells in terms of their support of either LTC-IC detection (CFC production) or maintenance (over a 6-week period), and all were equivalent to primary human marrow feeders (HMF). On the other hand, murine M2-10B4 fibroblasts engineered to produce high levels of both human granulocyte colony-stimulating factor (G-CSF) and interleukin-3 (IL-3; 190 and 4 ng/mL, respectively), either alone or mixed 1:1 with SI/SI fibroblasts engineered to produce high levels of soluble Steel factor (SF), with or without production of the transmembrane form of SF (60 and 4 ng/ mL, respectively), stimulated the production of up to 20- fold more CFC in LTC of cells from normal human marrow, G-CSF-mobilized blood or cord blood when compared with parallel cocultures containing HMF. Limiting dilution analysis of the CFC output from all three sources of LTC-IC showed that most of this increase was due to an ability of the engineered feeders to increase the plating efficiency of the LTC-IC assay (approximately 14-fold for marrow LTC-IC and approximately 4-fold for cord blood or mobilized blood LTC-IC). Analysis of the phenotype of these additionally recruited LTC-IC from marrow showed they had the same primitive CD34+CD45RA-CD71- phenotype as conventionally defined LTC-IC. The limiting dilution studies also showed that the average number of CFC produced per LTC-IC was additionally and independently increased to yield values of 18 CFC per LTC-IC in marrow, 28 for LTC-IC in cord blood, and 25 for LTC-IC in G- CSF-mobilized blood. Replating of cells from primary LTC with different feeders into secondary LTC-IC assays containing the best combination of engineered feeders showed that LTC-IC maintenance could be significantly enhanced (up to 7-fold as compared with primary cocultures containing HMF). However, this enhancement was still not sufficient to amplify the number of LTC-IC present after 6 weeks above the input value. Thus, engineering murine fibroblasts to produce sufficient SF, G-CSF, and IL-3 can markedly enhance the detection as well as the maintenance in vitro of a very primitive population of human progenitor cells present in normal adult marrow, mobilized blood, and cord blood by providing the most sensitive assay conditions thus far described. The present findings also provide new evidence of biologic heterogeneity between different cell populations that can be operationally identified as LTC-IC, thus re-emphasizing the importance of limiting dilution analyses to distinguish between quantitative and qualitative effects on these cells.     

Synergistic effects of pegylated recombinant human megakaryocyte growth and development factor and granulocyte colony-stimulating factor on mobilization of hematopoietic progenitor and stem cells with long-term repopulating ability into peripheral blood in mice

We investigated the effects of pegylated recombinant human megakaryocyte growth and development factor (PEG-rHuMGDF) on peripheral blood progenitor cell (PBPC) mobilization and the combined effect of PEG-rHuMGDF plus recombinant human granulocyte colony-stimulating factor (rhG-CSF) in C57BL/6 mice. Treatment of mice with PEG-rHuMGDF increased the numbers of day 8 and day 12 spleen colony-forming units (CFU-S), and pre-CFU-S in the PB. Ten days administration of PEG-rHuMGDF could mobilize higher numbers of days 8 and day 12 CFU-S than 5 days administration. An optimal dose of PEG-rHuMGDF mobilized a higher number of committed progenitor cells (day 8 CFU-S) and a lower number of immature progenitor cells (pre-CFU-S) into PB than rhG-CSF. The combined administration of optimal or suboptimal doses of PEG-rHuMGDF and rhG-CSF induced synergistic effects on mobilization of CFU-S and pre-CFU-S into PB compared to either factor alone. Four months after sex-mismatched PBPC transplantation, long-term donor-derived engraftment was observed in all recipients that had been transplanted with PBPCs mobilized by rhG-CSF and/or PEG-rHuMGDF, as determined by Y-chromosome polymerase chain reaction (PCR) analysis. Our data suggest that cytokine-induced pathways for PBPC mobilization may be different between PEG-rHuMGDF and rhG-CSF and indicate that PEG-rHuMGDF alone or the combination with rhG-CSF may be useful in effective PBPC mobilization.     

Bone marrow harvest for marrow transplantation: effect of multiple small (2 ml) or large (20 ml) aspirates.

The aim of this study was to evaluate the yield of nucleated cells and CFU-GM and the T cell composition in bone marrow harvested by means of multiple small (2 ml) or large (20 ml) aspirations. Eleven marrow donors were studied: each donated 1000 ml of bone marrow in two aliquots of 500 ml for an HLA identical sibling transplant. In six cases the first 500 ml were harvested by means of multiple 2 ml aspirations (A) and the second 500 ml by means of 20 ml aspirations (B). In five cases the opposite was done: 20 ml aspirates first (C) and 2 ml afterwards (D). From each 500 ml aliquot a sample was taken for enumeration of nucleated cells and CD3+ lymphocytes and for CFU-GM growth. Small volume aspirations (groups A and D) yielded more nucleated cells (p = 0.02), more CFU-GM (p = 0.03) and fewer CD3+ cells (p = 0.1) when compared with large volume aspirations (groups B and C). This study shows that marrow harvesting by means of multiple small volume aspirations minimizes the dilution with peripheral blood and results in greater numbers of cells and hemopoietic progenitors.     

Characterization of primitive subpopulations of normal and leukemic cells present in the blood of patients with newly diagnosed as well as established chronic myeloid leukemia

Elevated numbers of primitive Philadelphia chromosome-positive (Ph+) progenitors, including long-term culture-initiating cells (LTC-IC) as well as colony-forming cells (CFC), have been previously described in the blood of patients with chronic myeloid leukemia (CML) in chronic phase with high white blood cell counts. In the present study, which focused primarily on an analysis of circulating progenitors present in such patients at diagnosis, we discovered the frequent and occasionally exclusive presence of circulating normal (Ph-) LTC-IC, often at levels above those seen for LTC-IC in the blood of normal individuals. The presence of detectable numbers of circulating Ph- LTC-IC was independent of the fact that the same peripheral blood samples also contained elevated numbers of predominantly or exclusively Ph+ CFC. Interestingly, both the Ph+ and Ph- LTC-IC in these samples were CD34+CD71- and variably CD38- and Thy-1+, as previously documented for LTC-IC in normal marrow. Thus, neither CD38 nor Thy-1 expression was useful for discriminating between Ph+ and Ph- LTC-IC in mixed populations. Nevertheless, an association of these phenotypes with LTC- IC function did allow highly enriched (> 5% pure) suspensions of either Ph+ or Ph- LTC-IC to be obtained from selected samples of CML blood in which the initial LTC-IC population was either predominantly Ph+ or Ph- , respectively. These findings suggest that the mechanisms causing mobilization of leukemic stem cells in untreated CML patients may affect their normal counterparts. They also indicate a possible new source of autologous cells for the support of intensive therapy of CML patients. Finally, they provide a method for obtaining the most highly purified populations of Ph+ LTC-IC described to date. This method should be useful for further analyses of the molecular activities of these very primitive neoplastic cells.     

Evaluation of the haemopoietic reservoir in de novo haemolytic paroxysmal nocturnal haemoglobinuria

Paroxysmal nocturnal haemoglobinuria (PNH) is an acquired clonal disorder of the haemopoietic stem cell (HSC). The pathogenetic link with bone marrow failure is well recognized; however, the process of clonal expansion of the glycosylphosphatidylinositol (GPI)-deficient cells over normal haemopoiesis remains unclear. We have carried out detailed analysis of the stem cell population in 10 patients with de novo haemolytic PNH using the long-term culture-initiating cells (LTC-IC) assay in parallel with measurements of CD34+ cells and mature haemopoietic progenitors, granulocyte-macrophage colony-forming unit (CFU-GM) and CFU-erythroid [burst-forming units erythroid (BFU-E) + CFU granulocyte/erythroid/macrophage/megakaryocyte (GEMM)]. All patients had hypercellular bone marrows with erythroid hyperplasia, normal blood counts or mild peripheral blood cytopenias, increased reticulocyte counts and evidence of deficient GPI-anchored proteins. We found a significant reduction in the LTC-IC frequency in the CD34+ compartment of PNH patients (mean 2, range 1.3-3.0; n=6) compared with normal donors (mean 13, range 5.2-45.5; n=21) (P<0.0001). Furthermore, there was a significant reduction in the erythroid compartment [CFU-E/105 bone marrow mononuclear cells (BMMC) and CFU-E/105 CD34+ cells] of PNH patients, but no significant difference in the granulocyte-monocyte precursors (CFU-GM/105 BMMC or CFU-GM/105 CD34+ cells) compared with normal donors, suggesting that there is a defect in the early stem cell pool in PNH patients without clinical or haematological evidence of bone marrow failure.     

Peripheral blood progenitor cell (PBPC) counts during steady-state haemopoiesis enable the estimation of the yield of mobilized PBPC after granulocyte colony-stimulating factor supported cytotoxic chemotherapy: an update on 100 patients

Peripheral blood progenitor cells (PBPC) can be mobilized using chemotherapy and granulocyte colony-stimulating factor (G-CSF). We and others previously reported a correlation of steady-state PBPC counts and the PBPC yield during mobilization in a small group of patients. Here we present data on 100 patients (patients: 25 non-Hodgkin's lymphoma (NHL), five Hodgkin's disease, 35 multiple myeloma (MM), 35 solid tumour) which enabled a detailed analysis of determinants of steady-state PBPC levels and of mobilization efficiency in patient subgroups. Previous irradiation (P = 0.0034) or previous chemotherapy in patients with haematological malignancies (P = 0.0062) led to a depletion of steady-state PB CD34+ cells. A correlation analysis showed steady-state PB CD34+ cells (all patients: r = 0.52, P < 0.0001; NHL patients, r = 0.69, P = 0.0003; MM patients: r = 0.66, P = 0.0001) and PB colony-forming cells can reliably assess the CD34+ cell yield in mobilized PB. In patients with solid tumour a similar trend was observed in mobilization after the first chemotherapy cycle (r = 0.51, P = 0.05) but not if mobilization occurred after the second or further cycle of a sequential dose-intensified G-CSF-supported chemotherapy regimen, when premobilization CD34+ counts were 18-fold elevated (P = 0.004). When the patients with MM (r = 0.63, P = 0.0008) or with NHL (r = 0.65, P = 0.006) were analysed separately, a highly significant correlation of the steady-state PB CD34+ cell count to the mean leukapheresis CD34+ cell yield was found, whereas no correlation was observed for patients with a solid tumour. For patients with haematological malignancies estimates could be calculated which, at a specific steady-state PB CD34+ cell count, could predict with a 95% probability a defined minimum progenitor cell yield. These results enable recognition of patients who mobilize PBPC poorly and may assist selection of patients for novel mobilization regimens.