Autologous transplantation of canine long-term marrow culture cells genetically marked by retroviral vectors.

Retroviral infection of bone marrow cells in long-term marrow cultures (LTMCs) offers several theoretical advantages over other methods for gene transfer into hematopoietic stem cells. To investigate the feasibility of this approach in a large animal model system, we subjected LTMCs from nine dogs to multiple infections with retrovirus containing the neomycin phosphotransferase gene (neo) during 21 days of culture. Feeder layers, cocultivation, polycations, and selection were not used. The in vitro gene transfer efficiency was 70% as determined by polymerase chain reaction amplification of neo sequences in colony-forming unit granulocyte-macrophage (CFU-GM) obtained from day-21 LTMCs. Day-21 LTMC cells were infused into autologous recipients with (four dogs) and without (three dogs) marrow-ablative conditioning. At 3 months posttransplant, up to 10% of marrow cells contained the neo gene. This percentage declined to 0.1% to 1% at 10 to 21 months posttransplant. Neo was also detected in individual CFU-GM, burst-forming unit-erythroid (BFU-E), and CFU-Mix progenitors derived from marrow up to 21 months postinfusion and in cultures of peripheral blood-derived T cells up to 19 months postinfusion. There was no difference in the percentage of neo-marked cells present when dogs that received marrow ablative conditioning were compared with dogs receiving no conditioning. Detection of neo-marked marrow cells almost 2 years after autologous transplantation in a large mammalian species shows that retroviral infection of marrow cells in LTMCs is a potentially nontoxic and efficient protocol for gene transfer. Further, our results suggest that marrow conditioning and in vivo selection pressure to retain transplanted cells may not be absolute requirements for the retention of genetically marked cells in vivo.     

Characterization of host cells involved in resistance to marrow grafts in dogs transplanted from unrelated DLA-nonidentical donors

A canine model of marrow transplantation was used to further define the host cells mediating resistance to marrow engraftment. Recipient dogs were given 9.2 Gy of total body irradiation followed by marrow infusion from unrelated DLA-nonidentical donors. No postgrafting immunosuppression was given. At three and ten days posttransplantation recipient marrow and peripheral blood cells were obtained and characterized by the following in vitro studies: morphologic analysis; phenotypic analysis with monoclonal antibodies; assays for natural killer cell (NK) activity; and cocultures with donor marrow to study the effect on donor CFU-GM growth. Daily differential cell counts revealed a proliferation of peripheral blood mononuclear cells approximately eight days posttransplant. By day 10 surviving host cells were uniformly large granular lymphocytes which were phenotypically of T cell lineage, had NK activity, and were capable of suppressing donor marrow CFU-GM growth. Mononuclear cells from dogs given total body irradiation only and no marrow infusion (radiation control group), did not suppress CFU-GM growth when cocultured with marrow from unrelated DLA-mismatched dogs. These results suggest that radioresistant host cells with the morphology of large granular lymphocytes and NK activity and which proliferate in response to the infused donor marrow cells mediate resistance to DLA-nonidentical marrow grafts. It remains to be determined, however, whether in vitro functional studies reflect the mechanisms involved in vivo.     

CFU-GM content of bone marrow graft correlates with time to hematologic reconstitution following autologous bone marrow transplantation with 4- hydroperoxycyclophosphamide-purged bone marrow

Autologous bone marrow transplants (BMTs) can repopulate the hematologic system of patients treated with marrow-ablative chemotherapy and/or radiotherapy. However, treatment of the bone marrow graft to eliminate residual tumor cells prior to reinfusion can delay the return of peripheral blood elements, presumably from damage to or loss of hematopoietic stem cells responsible for hematologic recovery. To develop a model predictive of hematologic recovery, we studied the progenitor cell contents of 4-hydroperoxycyclophosphamide (100 micrograms/mL)-purged bone marrow grafts of 40 consecutive patients undergoing autologous BMT at this center. Granulocyte-macrophage colonies (CFU-GM) were grown from all grafts after treatment with this chemotherapeutic agent, but erythroid (BFU-E) and mixed (CFU-GEMM) colonies were grown from only 44% and 33% of the grafts respectively. The recovery of CFU-GM after purging ranged from 0.07% to 23%. The logarithm of CFU-GM content of the treated grafts was linearly correlated with the time to recovery of peripheral blood leukocytes (r = -0.80), neutrophils (r = -0.79), reticulocytes (r = -0.60), and platelets (r = -0.66). The CFU-GM content of purged autologous bone marrow grafts may reflect the hematopoietic stem cell content of the grafts and thus predict the rate of hematologic recovery in patients undergoing autologous BMT.     

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.     

Cell-mediated inhibition of granulopoiesis in vitro in patients with acute myeloid leukemia in remission

We investigated the in vitro granulopoiesis in 11 patients with acute myeloid leukemia (AML) in complete remission 3-80 months after diagnosis (median 8.5 months). 3 of the patients had subnormal levels of bone marrow-derived CFU-GM. 6 of 10 patients tested had defective recloning capacity of d-7 CFU-GM, suggesting a stem cell defect. Most patients (7/11) showed an increased colony growth of bone marrow-derived CFU-GM after T-cell depletion by E-rosetting, while readdition of isolated autologous T cells to T-cell depleted marrow caused a dose-dependent inhibition of colony formation; bone marrow T cells were more effective in this inhibition than peripheral blood T cells. Experiments using cells depleted of either CD4- or CD8-positive cells and CD4/CD8-enriched cell populations showed that both CD4- and CD8-positive cells had the capacity to inhibit colony growth. Long-term culture of bone marrow cells in suspension showed that the production of CFU-GM declined at about the same rate as in normal controls. Our findings suggest that there are persisting stem cell defects in patients with AML in remission and that the cell growth regulatory systems may be altered. These abnormalities could possibly be an effect of residual damage to the hematopoietic system caused by intensive chemotherapy.     

Different repopulation kinetics of erythroid (BFU-E), myeloid (CFU-GM) and T lymphocyte (TL-CFU) progenitor cells after autologous and allogeneic bone marrow transplantation

Marrow recovery of erythroid (BFU-E), myeloid (CFU-GM) and T-lymphocyte (TL-CFU) progenitor cells was studied at various time intervals after autologous bone marrow transplantation in 10 patients with acute myeloid leukaemia in remission. These data were compared with those in 14 recipients of T-cell depleted allogeneic marrow grafts. The results indicate markedly different repopulation kinetics of BFU-E, CFU-GM and TL-CFU after autologous and allogeneic bone marrow transplantation. Following autografting reduced numbers of BFU-E and CFU-GM were always present at 2 months after transplantation. Between 2-6 and 6-24 months a gradual increase occurred, although reduced BFU-E and CFU-GM values were still noted in 50% of the cases in spite of normal bone marrow cellularity and restoration of peripheral blood counts. In contrast, in the allograft recipients normal BFU-E numbers appeared within 2 months after transplantation. In addition, CFU-GM values had become normal in 35% of the tests performed at 1-2 months and respectively in 66% and 100% at 2-6 and 6-24 months. The recovery pattern of TL-CFU differed from that of the other haemopoietic progenitor cells. TL-CFU showed a fast recovery, i.e. within 1 month after autologous bone marrow transplantation which was much more rapid than that of BFU-E and CFU-GM. After allografting, however, TL-CFU regenerated at a slower rate and reached normal levels between 2 and 6 months after transplantation. We suggest that the delayed restoration of myeloid and erythroid progenitor cells after autologous transplantation is related to a proliferative defect of the graft as a result of the preceding cytotoxic chemotherapy, the underlying malignant disease and/or cryopreservation. The slower recovery of the T lymphocyte precursors after allografting might be due to the immunological interactions between graft and host, the immuno-suppressive therapy and/or the in vitro T cell depletion of the graft.     

Purification of murine bone-marrow-derived granulocyte-macrophage colony-forming cells

Previous attempts to purify progenitor cells that form colonies and clusters of granulocytes and/or macrophages (CFU-GM) from adult murine bone marrow have had limited success because of the paucity of these cells. In the present paper we report studies with a rapid, reproducible method involving pretreatment of mice, three days prior to sacrifice, with 200 mg/kg of Cytoxan (cyclophosphamide), density separation on Ficoll-Hypaque, and counterflow centrifugal elutriation, that yielded highly enriched populations of CFU-GM. The peak CFU-GM-containing fraction (FR-28) eluted at a flow rate of 28 ml/min and contained very little contamination by other in vitro colony-forming cells (BFU-E, CFU-GEMM, CFU-MK). FR-28 contained 0.54% +/- 0.30% (16 experiments) of the unfractionated post-Cytoxan bone marrow nucleated cells and lacked significant contamination by lymphocytes and monocytes. The mean CFU-GM cloning efficiency of FR-28 was 44% +/- 9% in agar (11 experiments) and 75% +/- 10% in agarose (nine experiments). CFU-GM from FR-28 demonstrated linear plating characteristics even at very low cell density (25 cells), and formed colonies and clusters of granulocytes, macrophages, or both in the same proportions as did unfractionated post-Cytoxan or untreated bone marrow. Approximately 10% (assuming a seeding efficiency of 10%) of FR-28 cells were in vivo spleen colony-forming cells (CFU-S) measured at day 12. These results represent the highest degree of purity (up to 94%) of CFU-GM thus far reported and should prove useful in studies of this cell population.     

脐血干细胞与骨髓干细胞联合移植治疗大鼠急性肝衰竭实验研究

目的：观察脐血干细胞和自体骨髓干细胞共同移植治疗D-半乳糖苷所致急性肝衰竭大鼠的疗效。方法采集大鼠脐血和骨髓中单个核细胞,以促肝细胞生长因子和干细胞因子培养3w,采用免疫细胞化学法检测白蛋白和甲胎蛋白表达情况;以D-半乳糖苷腹腔注射法建立大鼠急性肝衰竭模型,24 h后每日经鼠尾静脉分别注入脐血干细胞,或骨髓干细胞,或混合的脐血干细胞和骨髓干细胞,对照组注射等量生理盐水,治疗7d,观察4组大鼠存活率、肝功能和肝组织病理学变化。结果在促肝细胞生长因子及干细胞因子的诱导下,脐血干细胞和骨髓干细胞可以在体外扩增并分化为肝细胞;脐血干细胞移植、骨髓干细胞移植和联合细胞移植组大鼠9d 存活率分别为55.6%、50.0%和77.8%,均明显高于生理盐水对照组（16.7%,P〈0.01）;联合移植组存活率高于任何一种单纯干细胞移植（P〈0.01）。结论脐血干细胞和骨髓干细胞移植对大鼠急性肝损伤有一定的保护作用,两者联合移植有协同作用。     

Culture of phenotypically defined hematopoietic stem cells and other progenitors at limiting dilution on Dexter monolayers.

Highly enriched, phenotypically defined hematopoietic stem, Thy-1loLin-Sca-1+, and progenitor cell populations from mouse bone marrow (BM) were tested at limiting dilution for their ability to reconstitute Dexter monolayers. Several classes of BM cells can reconstitute Dexter cultures, first forming discrete "cobblestone" areas which then mature into colonies consisting primarily of maturing myeloid and erythroid cells. Most such colonies have a limited lifespan in culture. Only the Thy-1loLin-Sca-1+ cell fraction gives rise to colonies that survive longer than 3 weeks, which suggests that a limiting-dilution analysis for long-term reconstitution of Dexter cultures can serve as a quantitative measure of stem cell activity. Additional experiments were performed to assess the formation of new progenitor cells in reconstituted Dexter cultures. Again, only cultures seeded with the stem cell-enriched fraction contained expanded numbers of replatable WEHI-3 CM responsive colony-forming cells (CFU-GM). Quantitative analysis indicates that 97% of the replatable CFU-GM of whole BM is contributed by the Thy-1loLin-Sca-1+ cell fraction, again suggesting a potential stem cell-specific assay. Such quantitative in vitro assays might prove useful in characterization and isolation of human stem cells where in vivo assays are lacking.     

Long-term bone marrow culture in Fanconi's anaemia

Summary. Fanconi's anaemia (FA) is the most common of the constitutional aplastic anaemias; the mechanisms leading to aplasia in this disease are poorly understood. A number of mechanisms have been implicated in the pathogenesis of acquired aplastic anaemia (AA), including a stem cell defect, an immune reaction against haematopoietic cells or defective function of the marrow microenvironment. To investigate the pathophysiology of this disorder we have performed bone marrow colony forming unit-granulocyte macrophage (CFU-GM) assays and long-term bone marrow culture (LTC) in 22 cases of FA compared with 17 cases of acquired AA.
Defective in vitro haematopoiesis was observed in all patients with FA, including several cases with normal peripheral blood counts. The mean CFU-GM value for the FA group was approximately 15 times lower than for the normal group. A correlation was seen between CFU-GM and the severity of neutropenia in FA. In LTC an adherent layer formed in all cases of FA; despite this fact CFU-GM were either not generated or rapidly fell to zero in all patients. LTC is a sensitive method for the detection of impaired granulopoiesis in FA and reveals defects in all patients with this disease.     

Recovery of circulating haemopoietic progenitor cells in the early phase of haemopoietic reconstitution after autologous and allogeneic bone marrow transplantation

The recovery of circulating haemopoietic progenitor cells was evaluated serially in seven patients for 3-4 weeks after bone marrow transplantation (two autologous and five allogeneic) as treatment for leukaemia. Eight normal healthy volunteers were used as controls. CFU-G (colony forming unit-granulocyte) was found to be the earliest progenitor cell to recover at a mean interval of 16 +/- 1 (SE) days post-transplantation. A lag of 7 days was found before circulating CFU-GM (colony forming unit-granulocyte, monocyte) reappeared, while BFU-E (burst forming unit-erythroid) were detectable in only two patients in the first 4 weeks. The peak level of circulating progenitors was very low, 28 +/- 8/ml, compared with a mean level of 619 +/- 235/ml in eight normal individuals. This pattern of circulating progenitor cell recovery post-transplantation was consistently seen in all patients. CFU-G reappeared significantly earlier than CFU-GM suggesting that early granulocytic recovery after bone marrow transplantation is mediated by proliferation of mature progenitors committed to the granulocytic lineage, whereas later reconstitution is accompanied by the emergence of CFU-GM.     

Detection of the target progenitor cells of granulomonopoietic enhancing activity

Macrophage-derived granulomonopoietic enhancing activity (GM-EA) is a novel mediator that amplifies colony formation of myeloid progenitor cells (CFU-GM) in conjunction with colony-stimulating factors (CSFs), and is distinct from other hematopoietic synergizing factors such as interleukin (IL)-1, IL-4, and IL-6. In the present study, we try to ascertain whether or not there is a GM-EA-specific responsive myeloid progenitor cell population. Human bone marrow cells deleted of adherent cells and T lymphocytes were separated by velocity sedimentation into three subpopulations with respective sedimentation rates (millimeters per hour) of 7.4 +/- 0.4, 6.0 +/- 0.6, and 4.7 +/- 0.3. These subpopulations corresponded to the day 7 CFU-GM, day 14 CFU-GM, and the earlier myeloid progenitor cells, pre-CFU-GM, respectively. Pre-CFU-GM failed to respond to the colony-inducing effect of GM-CSF but could be stimulated by GM-EA alone to generate small clusters (5 to 25 cells) in soft agar after 14 days of incubation. Correspondingly, suspension preculture of the fractionated bone marrow cells also showed that only the progenitor cells with low sedimentation rate (4.7 mm/h) could be activated by GM-EA to generate CFU-GM. Taken together, our results suggest that the specific target cell of GM-EA is the pre-CFU-GM, and that GM-EA acts on these cells as a growth/maturation factor, but on the day 7 and day 14 CFU-GM as a synergistic growth factor.     

A simple, efficient washing procedure for cryopreserved human hematopoietic stem cells prior to reinfusion.

We describe our experience with a washing procedure used on cryopreserved, thawed bone marrow (BM) and peripheral blood stem cell (PBSC) grafts prior to autologous transplantation in 50 and 12 patients respectively. The procedure consists of a stepwise dilution with 2% human serum albumin and centrifugation performed either manually or using a blood cell processor (Cobe 2991). In vitro studies showed mean recoveries of 80.8% for BM nucleated cells and 73.9% for BM hematopoietic progenitors (CFU-GM). The corresponding recoveries for PBSC were 89.1 and 93.9%. After 4 h storage at +20 degrees C of the manipulated grafts, no significant loss of CFU-GM was observed. We conclude that the technique is simple and efficient for washing large numbers of hematopoietic stem cells. This method may avoid the clinical complications often arising with unwashed grafts.     

Canine blood mononuclear cells mediate contact-dependent impairment of granulocyte-macrophage colony formation by bone marrow cells

Nonphagocytic, nonadherent mononuclear cells from canine peripheral blood (PBMC) were shown to suppress colony formation in agar of autologous and allogeneic bone marrow granulocyte-macrophage progenitor cells (CFU-GM). Suppression required previous cell-to-cell contact in liquid culture between PBMC and bone marrow cells (BMC) and was time- and dose-dependent and resistant to x-irradiation with 20 Gy. Small BMC were less susceptible than large BMC, whereas day-7 and day-14 CFU-GM were equally suppressed. Cryo-preservation of BMC did not enhance CFU-GM inhibition. Spontaneous inactivation during liquid culture of CFU-GM or accessory cells by PBMC is the likely effector mechanism. Possible recognition structures are different from dog leukocyte antigens A and B. Canine PBMC or subpopulations thereof might participate in the regulation of normal hemopoiesis and in the rejection of hemopoietic stem cell grafts by natural killer cell-like mechanisms as has been suggested for human and murine natural killer cells.     

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.     

Increase of high fluorescence reticulocytes indicates mobilization of peripheral stem cells in children recovering from aplasia after chemotherapy or bone marrow transplantation

Enumeration of CD34 + cells is the standard assay procedure for optimization of peripheral blood stem cell harvesting. High fluorescence reticulocytes (HFR) have been shown to signal a rebound in haematopoiesis after chemotherapy. The aim of this study was to evaluate HFR determination, as compared to CD34 + cell counts and CFU-GM, as a potential predictor of PBSC counts after recovery from chemotherapy and/or bone marrow transplantation. Twenty-five paediatric patients undergoing intensive courses of chemotherapy and 9 undergoing bone marrow auto or allografts were investigated. In most of our cases, HFR recovered at the same time or earlier than CD34 + cells. Similarly, the rise in HFR preceeded the CFU-GM peak in most of these cases. In no case did we observe a CFU-GM peak without a rise in HFR%. In our experience, the daily relative HFR increase may be used to predict the optimal time for mobilization of stem cells and was therefore of value clinically to confirm the timing of apheresis.     

Modulation of responsiveness of chronic myelogenous leukemia granulocyte-macrophage colony-forming cells to growth regulation following in vivo treatment with recombinant gamma-interferon

A patient with Philadelphia chromosome (Ph) chronic myelogenous leukemia (CML), in chronic phase, was treated with recombinant gamma-interferon (r gamma-IFN) in a phase I clinical trial. Prior to treatment, analysis of in vitro agar culture parameters indicated hyporesponsiveness of granulocyte-macrophage colony-forming cells (CFU-GM) to inhibition by prostaglandin E and acidic isoferritins and diminished expression of class II major histocompatibility complex (MHC) antigens (HLA-DR). Treatment was associated with no change in bone marrow cellularity or in the percentage of Ph cells. However, in vitro cultures of bone marrow cells showed a return to normal levels of both expression of CFU-GM class II antigen and of sensitivity to inhibition by prostaglandin E and acidic isoferritins which predicted and/or confirmed clinical response. Throughout the course of interferon therapy, white blood cell counts (WBC) and the percentage of bone marrow blast cells were maintained at normal levels. Onset of aggressive-phase disease was associated with increased WBC, an increase in bone marrow blast cells, a secondary chromosomal abnormality, loss of CFU-GM sensitivity to inhibition by putative negative growth regulators, and markedly diminished MHC class II antigen expression. Following a bone marrow transplant from a matched sibling, all hematologic parameters studied were found to be normal. These findings indicate that treatment with r gamma-IFN can modulate some of the abnormal growth characteristics of CFU-GM observed in CML.     

Enhanced colony formation of human hemopoietic stem cells in reduced oxygen tension

In general, cell cultures, including hemopoietic stem cells, are produced in an atmosphere of various CO2 concentrations in air, although most cells in vivo proliferate and differentiate at lower oxygen tensions. We therefore investigated the effect of reduced oxygen tension on the in vitro colony growth of committed and multipotential hemopoietic progenitor cells from human bone marrow. All hemopoietic progenitor cells (CFU-mix, BFU-E, CFU-E, and CFU-GM) investigated showed enhanced colony growth at lower oxygen tension. CFU-E showed the highest enhancement, followed in order by BFU-E, CFU-mix and CFU-GM. At reduced oxygen tension, the sensitivity of early and late erythroid progenitor cells to erythropoietin was significantly increased, and this can be one of the mechanisms for the enhanced colony growth of erythroid progenitors. In the colony growth of CFU-GM, plating efficiency was also enhanced by the predominant increment of neutrophilic colonies. The lowering of oxygen tension would presumably reduce oxygen toxicity and result in the increased colony growth of human bone marrow stem cells, although the precise mechanisms of oxygen toxicity at the level of hemopoietic stem cells have yet to be elucidated. However, this clonal culture system, using a low oxygen tension, can be a useful means for elucidating the regulatory mechanisms involved in the proliferation and differentiation of hemopoietic progenitor cells in physiological and pathological conditions.     

Retrovirus-mediated gene transduction into long-term repopulating marrow cells of dogs.

Amphotropic helper-free retrovirus vectors containing the bacterial neomycin phosphotransferase gene (neo) and the human adenosine deaminase gene (adenosine aminohydrolase, EC 3.5.4.4; ADA) were used to transduce canine marrow cells. In one approach, dogs were treated for 7 days with recombinant human granulocyte colony-stimulating factor to stimulate hematopoietic cell division. Bone marrow cells were collected and transduced by 24 hours of cocultivation on vector-producing cells followed by incubation in a vector-containing long-term marrow culture system for 4 days. Transduced autologous marrow (0.4 to 1.0 x 10(8) cells/kg) was infused into dogs administered otherwise lethal total body irradiation (TBI) of 920 cGy. Two of four dogs engrafted, and their marrows showed intermittently between 1% and 11% G418-resistant colony-forming unit granulocyte-macrophage (CFU-GM) colonies for up to 2 years after transplantation. In a different experimental approach, autologous marrow, obtained at the time of the PB neutrophil nadir 7 days after a single cyclophosphamide injection (40 mg/kg intravenously), was cocultivated for 24 hours on vector-producing cells and infused at doses of 0.06 to 0.18 x 10(8) cells/kg into dogs administered 920 cGy TBI. One of three dogs engrafted, and the marrow showed intermittently 1% to 10% G418-resistant CFU-GM colonies for at least 2 years. Culture results were confirmed by polymerase chain reaction (PCR) showing the presence of the neo gene in marrow cells, peripheral blood (PB) granulocytes, and PB and lymph node lymphocytes. Dilution experiments indicated that up to 10% of marrow, lymph node, and PB cells contained the neo gene, consistent with the culture results. Samples harboring the neo gene also contained the gene for human ADA. However, repeated analyses of PB and marrow cells for human ADA gene expression by starch gel electrophoresis were negative. PB samples of all dogs were free of helper virus, and no long-term side effects from the transduction were observed.     

Marrow repopulating cells, but not CFU-S, establish long-term in vitro hemopoiesis on a marrow-derived stromal layer

We have studied the ability of subpopulations of hemopoietic stem cells, obtained from murine bone marrow using elutriation and multiparameter sorting, to establish and maintain hemopoiesis following their deposition on irradiated stromal layers of long-term bone marrow cultures. Two fractions were obtained that differed in their mitochondrial activity as indicated by the retention of Rhodamine-123 dye. The Rhodamine-bright cell fraction, containing the majority of day-8 and day-12 spleen colony-forming units (CFU-S) and in vitro clonable progenitors, showed hemopoiesis only in the first weeks. In contrast, the Rhodamine-dull fraction, which was depleted for day-8 CFU-S and which contained the majority of cells with marrow-repopulating ability, maintained hemopoiesis for a prolonged time after an initial week of delay. These data fully support and extend previously published in vivo data, indicating that CFU-S have low capability to generate new CFU-S and granulocyte-macrophage colony-forming units (CFU-GM), and that cells responsible for long-term generation of hemopoietic precursors and for maintenance of hemopoiesis both in vivo and in vitro are the precursors of CFU-S and of in vitro clonable progenitor cells. In addition, the present findings form the basis for an in vitro assay for a primitive precursor of CFU-S, namely the marrow-repopulating cell.