A newly discovered class of human hematopoietic cells with SCID-repopulating activity

Applications of flow cytometry to hematopoietic stem cell transplantation

Applications of flow cytometry to clinical and experimental hematopoietic stem cell transplantation (HSCT) are discussed in this review covering the following topics: diagnosis and classification of lymphohematologic disorders, quantitation of hematopoietic progenitors in the graft, lymphohematopoietic reconstitution following HSCT and animal models of human HSCT. At the end, the utilization of flow cytometry in clinical HSCT by Brazilian transplant centers is briefly reviewed.

Molecular cloning and chromosomal mapping of a candidate cytokine gene selectively expressed in human CD34+ cells

A rare population of human bone marrow (BM) and cord blood (CB) mononuclear cells bearing the CD34 surface marker (CD34+) function as hematopoietic stem/progenitor cells. Cells lacking CD34 expression (CD34-) in BM and CB are largely mature hematopoietic cells of various lineages that are derived from the CD34+ cells. To elucidate molecular mechanisms governing functional differences between CD34+ and CD34- hematopoietic cells, we used representational difference analysis (RDA)-based subtraction to identify genes that are specifically or preferentially expressed in CD34+ cells. Among the 73 RDA fragments initially sequenced, 30% are derived from the CD34 and c-kit genes that are preferentially expressed in CD34+ cells. An additional 27 (37%) are novel or homologous only to entries in expressed sequence tag databases. One (C17) was found four times and is expressed in CD34+ but not in CD34- cell populations from CB or BM. The cloned C17 cDNA encodes a novel polypeptide of 136 amino acids with a signal sequence. No homology to this peptide was found in the public databases. A secondary-structure analysis predicts that the C17 peptide contains four alpha-helices, a characteristic of hematopoietic cytokines and interleukins. This novel gene is mapped to human chromosome 4p15-p16.

Differential engraftment of genetically modified CD34(+) and CD34(-) hematopoietic cell subsets in lethally irradiated baboons

OBJECTIVE

To test gibbon ape leukemia virus (GALV) pseudotype vector transduction of marrow subpopulations that contribute to hematopoietic reconstitution in vivo.

MATERIALS AND METHODS

Autologous CD34(+) Lin(-), CD34(+) Lin(+), and CD34(-) Lin(-) marrow cells, transduced by coculture with PG13/LN, PG13/LNX, and PG13/LNY vector-producing cells, respectively, were transplanted in three female baboons. Two female baboons also were transplanted with fresh allogeneic CD34(-)Lin(-) marrow cells from MHC-matched male siblings and, to ensure survival, with autologous CD34(+)Lin(-) and CD34(+)Lin(+) marrow cells transduced with PG13/LN and PG13/LNX, respectively. The LN, LNX, and LNY vectors are identical except for different length sequences at the 3' end of the bacterial neomycin phosphotransferase (neo) gene.

RESULTS

LN(+) and LNX(+) cells from CD34(+)Lin(-) and CD34(+)Lin(+) cells, respectively, but no LNY(+) from CD34(-)Lin(-) cells were detectable in blood and marrow of all animals after transplant. LN(+), CD34(+)Lin(-) cells contributed to reconstitution of the T, B, and myeloid lineages. LNX(+), CD34(+)Lin(+) cells contributed only to B and myeloid lineages. Male cells, CD34(-)Lin(-), were detected by polymerase chain reaction in blood and marrow of the two allogeneic transplanted animals at estimated frequencies of </=0.001% 1 month after transplant in both animals. Male cells became undetectable in one animal and have remained detectable, with declining frequency, in the other for more than 15 months. In this animal, no male CD34(+) or colony-forming cells have been detected.

CONCLUSIONS

CD34(+)Lin(-) and CD34(+)Lin(+) marrow cells can serve as targets for GALV pseudotype retrovirus-mediated gene transfer. CD34(+)Lin(-) cells contribute to reconstitution of all hematopoietic lineages. Autologous CD34(-)Lin(-) cells were either not transduced by GALV pseudotype retrovirus vectors using current approaches or did not contribute significantly to reconstitution, as suggested by allogeneic transplants.

CD34: to select or not to select? That is the question

Recent evidence suggests that expression of CD34 on the cell membrane does not always correlate with stem cell activity. In the mouse, there is a highly quiescent population of stem cells that lacks CD34 expression, but has full reconstituting capacity. The current review addresses the discovery of a similar population of dormant CD34-negative human hematopoietic stem cells. This information casts some uncertainty on the benefits of CD34+ cell isolation for stem cell transplantation, until more is known about the novel CD34-negative stem cell population. Methods designed to achieve removal of specific mature blood cell lineages might prove to be most advantageous in the future.

Efficiency of transgenic T cell generation from gene-marked cultured human CD34+ cord blood cells is determined by their maturity and the cytokines present in the culture medium

Success of gene therapy for diseases affecting the T cell lineage depends on the thymic repopulation by genetically engineered hematopoietic progenitor cells (HPC). Although it has been shown that retrovirally transduced HPC can repopulate the thymus, little information is available on the effect of the culture protocol. Moreover, for expansion of the number of HPC, cytokine supplemented culture is needed. Here, we transduced purified human umbilical cord blood (CB) CD34+ cells in cultures supplemented with various combinations of the cytokines thrombopoietin (TPO), stem cell factor (SCF), flt3/flk-2 ligand (FL), interleukin-3 (IL-3) and IL-6, and investigated thymus-repopulating ability of gene-marked HPC in vitro. Irrespective of the cytokine cocktail used, transduced CD34+CD38- CB cells, expressing the marker green fluorescent protein (GFP) encoded by the MFG-GFP retrovirus, have both superior proliferative and thymus-repopulating potential compared with transduced CD34+CD38+ CB cells. Effectively transduced GFP+CD34+CD38- HPC, cultured for 3 or 17 days, more readily generated T cells than GFP- HPC from the same culture. The reverse was true in the case of CD34+CD38+ HPC cultures. Finally, our results indicate that the number of GFP+ T cell progenitors actually increased during culture of CD34+CD38- HPC, in a magnitude that is determined by the cytokine cocktail used during culture.

Selective elimination of leukemic CD34+ progenitor cells by cytotoxic T lymphocytes specific for WT1

Hematologic malignancies such as acute and chronic myeloid leukemia are characterized by the malignant transformation of immature CD34+ progenitor cells. Transformation is associated with elevated expression of the Wilm's tumor gene encoded transcription factor (WT1). Here we demonstrate that WT1 can serve as a target for cytotoxic T lymphocytes (CTL) with exquisite specificity for leukemic progenitor cells. HLA-A0201– restricted CTL specific for WT1 kill leukemia cell lines and inhibit colony formation by transformed CD34+ progenitor cells isolated from patients with chronic myeloid leukemia (CML), whereas colony formation by normal CD34+ progenitor cells is unaffected. Thus, the tissue-specific transcription factor WT1 is an ideal target for CTL-mediated purging of leukemic progenitor cells in vitro and for antigen-specific therapy of leukemia and other WT1-expressing malignancies in vivo.

Selective elimination of leukemic CD34+ progenitor cells by cytotoxic T lymphocytes specific for WT1

Hematologic malignancies such as acute and chronic myeloid leukemia are characterized by the malignant transformation of immature CD34+ progenitor cells. Transformation is associated with elevated expression of the Wilm's tumor gene encoded transcription factor (WT1). Here we demonstrate that WT1 can serve as a target for cytotoxic T lymphocytes (CTL) with exquisite specificity for leukemic progenitor cells. HLA-A0201– restricted CTL specific for WT1 kill leukemia cell lines and inhibit colony formation by transformed CD34+ progenitor cells isolated from patients with chronic myeloid leukemia (CML), whereas colony formation by normal CD34+ progenitor cells is unaffected. Thus, the tissue-specific transcription factor WT1 is an ideal target for CTL-mediated purging of leukemic progenitor cells in vitro and for antigen-specific therapy of leukemia and other WT1-expressing malignancies in vivo.

Isolation of primary and immortalized CD34-hematopoietic and mesenchymal stem cells from various sources

Based on historical radiation experiments in rodents, the hematopoietic stem cell was defined by its biological properties and later by the expression of certain surface antigens (e.g., CD34), as well as the absence of lineage-specific markers (e.g., DR). Quite recently it was shown that hematopoietic reconstitution can also be achieved by CD34- stem cells, which can be isolated from the bone marrow, peripheral blood and cord blood cells. CD34-stem cells are considered to be predominately part of the quiescent stem cell pool of hematopoietic and mesenchymal stem cells. Due to novel techniques, CD34-stem cells can be expanded on the level of a true stem cell but also directed towards their differentiation into specified tissues or organ systems. This requires the establishment of primary fibroblast-like CD34- stem cells in vitro and their possible reversible and transient immortalization with optimized vector systems.

Circulating hematopoietic progenitor cells in first trimester fetal blood

The yolk sac and aorto-gonad-mesonephros region are well recognized as the principal sites of hematopoiesis in the developing embryo, and the liver is the principal site of hematopoiesis in the fetus. However, little is known about circulating hematopoietic stem and progenitor cells in early fetal life. We investigated the number and characteristics of circulating progenitors in first trimester blood of 64 human fetuses (median gestational age, 10+4 weeks; range, 7+6-13+6 weeks). CD34+ cells accounted for 5.1 ± 1.0% of CD45+ cells in first trimester blood, which is significantly more than in term cord blood (0.4 ± 0.03%;P = .0015). However, the concentration of CD34+ cells (6.6 ± 2.4 × 104/mL) was similar to that in term cord blood (5.6 ± 3.9 × 104/mL). The total number of progenitors cultured from unsorted mononuclear cells (MNCs) in first trimester blood was 19.2 ± 2.1 × 103/mL, which is similar to that in term cord blood (26.4 ± 5.6 × 103/mL). All lineages were seen: colony-forming unit–GEMM (CFU-GEMM), CFU-GM, BFU-e, BFU-MK, and CFU-MK. Clonogenic assays of CD34+ cells purified from first trimester samples produced mainly two lineages: BFU-e (39.0 ± 9.6 × 103/mL CD34+ cells) and CFU-GEMM (22.6 ± 4.7 × 103/mL CD34+ cells). Short-term liquid culture of first trimester blood MNCs in SCF + IL-3 + Flt-3 (stem cell factor + interleukin-3 + Flt-3) increased, by 7-fold, the numbers of CFU-GEMM and induced a dramatic increase in BFU-e (65.6 ± 12.1–fold). These data show that significant numbers of committed and multipotent progenitors with capacity for expansion circulate in first trimester fetal blood and can be CD34 selected. These cells should be suitable targets for gene transfer and stem cell transplantation and, because fetal hematopoietic progenitors have been demonstrated in the maternal circulation from early gestation, may also be manipulated for noninvasive prenatal diagnosis of major genetic disorders.

Enrichment of lineage-CD34- cells using a newly developed filter system

Recent studies have demonstrated the presence of human lineage- (lin-)CD34- cells that are capable of differentiating into CD34+ cells in xenogeneic transplantation systems. We developed a new filter system that can enrich lin-CD34- cells, a precursor cell population of CD34+ cells. The filter consists of polyethylene terephthalate non-woven fabrics coated with hydrophilic polymer. The frequency of lin-CD34- cells in the cell population after filtration was 7.45 +/- 4.41%, a 16.8 +/- 8.81-fold enrichment compared with 0. 49 +/- 0.31% in the cell population before filtration. The mean recovery of lin-CD34- cells was 48.57 +/- 13.59% (n = 15). Purified lin-CD34- cells, obtained by sorting the filtrated cell population, acquired CD34 expression and colony-forming activity after 7 d of culture. Our results indicate that this filter system is useful for isolating lin-CD34- cells, including precursors of CD34+ cells, and will help further the study of lin-CD34- cells.

Therapeutic relevance of CD34 cell dose in blood cell transplantation for cancer therapy

PURPOSE

To review recent advances in peripheral-blood progenitor-cell (PBPC) transplantation in order to define the optimal cell dose required for autologous and allogeneic transplantation.

MATERIALS AND METHODS

A search of MEDLINE was conducted to identify relevant publications. Their bibliographies were also used to identify further articles and abstracts for critical review.

RESULTS

The CD34(+) cell content of a graft is regarded as an accurate predictor of engraftment success. Postchemotherapy autologous PBPC transplantation with >/= 5 x 10(6) CD34(+) cells/kg body weight leads to more rapid engraftment than does transplantation of lower cell doses. Further increases in transplant cell dose further accelerate platelet but not neutrophil engraftment. Evidence that long-term hematopoietic recovery may be more accurately predicted by the subpopulation of primitive progenitors transplanted suggests that the content of CD34(+)CD33(-) and long-term culture-initiating cells in cell collection samples may be important for predicting successful engraftment, particularly in patients with poor mobilization. Allogeneic transplantation has been limited by concerns regarding graft-versus-host disease and the use of hematopoietic growth factors in donors. The risk of graft rejection and engraftment failure after HLA-mismatched allogeneic transplantation may be overcome by intensive chemoradiotherapy and the infusion of large numbers of T cell-depleted hematopoietic stem cells.

CONCLUSION

An optimal cell dose of >/= 8 x 10(6) CD34(+) cells/kg seems to be recommended for autologous PBPC transplantation. This dose facilitates the administration of scheduled chemotherapy on time and reduces the demand for other supportive therapies. A combination of growth factors may enable patients with poor mobilization to achieve a collection sufficient to allow transplantation. The optimum PBPC dose for allogeneic transplantation remains to be defined.

Translating stem and progenitor cell biology to the clinic: barriers and opportunities

Stem cells are the natural units of embryonic generation, and also adult regeneration, of a variety of tissues. Recently, the list of tissues that use the model of differentiation from stem to progenitor to mature cell has increased from blood to include a variety of tissues, including both central and peripheral nervous systems and skeletal muscle; it is also possible that all organs and tissues are derived from, and still contain, stem cells. Because the number and activities of stem cells and their progeny are homeostatically regulated, clinical stem cell transplantation could greatly add to the physician's armamentarium against degenerative diseases.

Expression of CD27 on murine hematopoietic stem and progenitor cells

Hematopoietic stem cells (HSC) are defined by self-renewal and multilineage differentiation potentials. In order to uncover the genetic program of HSC, we utilized high-density arrays to compare gene expression in highly purified mouse HSC and their mature progeny. One molecule specifically expressed in immature cells is CD27, a member of the TNF receptor family previously shown to play roles in lymphoid proliferation, differentiation, and apoptosis. We show here that the CD27 protein is expressed by about 90% of cells in a purified HSC population. Interestingly, the CD27pos cells are enriched for cells with short-term hematopoietic activities (colony forming potential in vivo and in vitro), while the minority CD27neg population is more effective in clonal long-term transplantation.

Development and analysis of transgenic mice expressing porcine hematopoietic cytokines: a model for achieving durable porcine hematopoietic chimerism across an extensive xenogeneic barrier

The capacity of mixed hematopoietic chimerism to induce tolerance has not been demonstrated in discordant xenogeneic species combinations because of the difficulty in achieving lasting hematopoietic engraftment. In an effort to create a model of long-lasting disparate xenogeneic hematopoietic chimerism, we have developed transgenic (Tg) mice carrying porcine cytokines. Three lines of Tg mice were generated: one carrying porcine IL-3 and GM-CSF genes only (termed IL/GM) and the remaining two lines carrying in addition, the soluble SCF gene (termed IL/GM/sS) or membrane-bound SCF gene (termed IL/GM/mS). Sera from mice with IL/GM and IL/GM/sS transgenes markedly stimulated the proliferation of swine marrow cells in vitro. However, proliferation of swine marrow cells was not induced in cultures containing IL/GM/mS sera. Consistent with these observations, ELISA assays revealed detectable levels of porcine cytokines in the sera of IL/ GM and IL/GM/sS, but not in sera of IL/GM/mS Tg mice. Marrow stromal cells prepared from all three kinds of Tg mice, but not those from non-Tg littermates, were capable of supporting the growth of porcine hematopoietic cells in vitro. Immunodeficient Tg mice were generated by crossing Tg founders with C.B-17 SCID mice for five generations. All Tg immunodeficient mice showed improved porcine hematopoietic engraftment compared with non-Tg controls. These Tg mice provide a useful model system for studying porcine hematopoietic stem cells, and for evaluating the feasibility of donor-specific tolerance induction by mixed chimerism across highly disparate xenogeneic barriers.

High levels of lymphoid expression of enhanced green fluorescent protein in nonhuman primates transplanted with cytokine-mobilized peripheral blood CD34+ cells

We have used a murine retrovirus vector containing an enhanced green fluorescent protein complimentary DNA (EGFP cDNA) to dynamically follow vector-expressing cells in the peripheral blood (PB) of transplanted rhesus macaques. Cytokine mobilized CD34+ cells were transduced with an amphotropic vector that expressed EGFP and a dihydrofolate reductase cDNA under control of the murine stem cell virus promoter. The transduction protocol used the CH-296 recombinant human fibronectin fragment and relatively high concentrations of the flt-3 ligand and stem cell factor. Following transplantation of the transduced cells, up to 55% EGFP-expressing granulocytes were obtained in the peripheral circulation during the early posttransplant period. This level of myeloid marking, however, decreased to 0.1% or lower within 2 weeks. In contrast, EGFP expression in PB lymphocytes rose from 2%-5% shortly following transplantation to 10% or greater by week 5. After 10 weeks, the level of expression in PB lymphocytes continued to remain at 3%-5% as measured by both flow cytometry and Southern blot analysis, and EGFP expression was observed in CD4+, CD8+, CD20+, and CD16/56+ lymphocyte subsets. EGFP expression was only transiently detected in red blood cells and platelets soon after transplantation. Such sustained levels of lymphocyte marking may be therapeutic in a number of human gene therapy applications that require targeting of the lymphoid compartment. The transient appearance of EGFP+ myeloid cells suggests that transduction of a lineage-restricted myeloid progenitor capable of short-term engraftment was obtained with this protocol.

Glass needle–mediated microinjection of macromolecules and transgenes into primary human blood stem/progenitor cells

A novel glass needle–mediated microinjection method for delivery of macromolecules, including proteins and larger transgene DNAs, into the nuclei of blood stem/progenitor cells was developed. Temporary immobilization of cells to extracellular matrix–coated dishes has enabled rapid and consistent injection of macromolecules into nuclei of CD34+, CD34+/CD38−, and CD34+/CD38−/Thy-1lo human cord blood cells. Immobilization and detachment protocols were identified, which had no adverse effect on cell survival, progenitor cell function (colony forming ability), or stem cell function (NOD/SCID reconstituting ability). Delivery of fluorescent dextrans to stem/progenitor cells was achieved with 52% ± 8.4% of CD34+ cells and 42% ± 14% of CD34+/CD38−cells still fluorescent 48 hours after injection. Single-cell transfer and culture of injected cells has demonstrated long-term survival and proliferation of CD34+ and CD34+/CD38−cells, and retention of the ability of CD34+/CD38− cells to generate progenitor cells. Delivery of DNA constructs (currently ≤ 19.6 kb) and fluorescently labeled proteins into CD34+ and CD34+/CD38− cells was achieved with transient expression of green fluorescent protein observed in up to 75% of injected cells. These data indicate that glass needle–mediated delivery of macromolecules into primitive hematopoietic cells is a valuable method for studies of stem cell biology and a promising method for human blood stem cell gene therapy.

A defined window for efficient gene marking of severe combined immunodeficient-repopulating cells using a gibbon ape leukemia virus-pseudotyped retroviral vector

We have investigated the minimal time required for efficient transduction of human hematopoietic repopulating cells using a surrogate nonobese diabetic (NOD)/severe combined immunodeficient (SCID) xenoengraftment assay. Cord blood CD34+ cells were transduced to high levels over 24-48 hr in the presence of Flt-3 ligand, stem cell factor, interleukin 3, and interleukin 6. Under these conditions, high levels of NOD/SCID repopulating activity were preserved, but the levels of gene marking in engrafting cell populations measured by expression of a reporter transgene were low. Extension of the transduction period by 24 hr (total culture period, 72 hr) under the same cytokine conditions resulted in high levels of gene marking, but on closer analysis expression was limited predominantly to the myeloid population. Efficient transduction of both lymphoid and myeloid lineages could be achieved only if the transduction protocol was extended by a further 24 hr (total culture period, 96 hr), suggesting that myeloid lineage-committed precursors are capable of repopulation, and that over shorter time periods transduction is largely restricted to this population. This adds to the emerging evidence of heterogeneity within the SRC compartment, and has important implications for the interpretation of this assay in stem cell transplantation and gene transfer studies.

Expansion of human cord blood CD34+CD38−cells in ex vivo culture during retroviral transduction without a corresponding increase in SCID repopulating cell (SRC) frequency: dissociation of SRC phenotype and function

Current procedures for the genetic manipulation of hematopoietic stem cells are relatively inefficient due, in part, to a poor understanding of the conditions for ex vivo maintenance or expansion of stem cells. We report improvements in the retroviral transduction of human stem cells based on the SCID-repopulating cell (SRC) assay and analysis of Lin− CD34+CD38−cells as a surrogate measure of stem cell function. Based on our earlier study of the conditions required for ex vivo expansion of Lin−CD34+ CD38− cells and SRC, CD34+–enriched lineage–depleted umbilical cord blood cells were cultured for 2 to 6 days on fibronectin fragment in MGIN (MSCV-EGFP-Neo) retroviral supernatant (containing 1.5% fetal bovine serum) and IL-6, SCF, Flt-3 ligand, and G-CSF. Both CD34+CD38− cells (20.8%) and CFC (26.3%) were efficiently marked. When the bone marrow of engrafted NOD/SCID mice was examined, 75% (12/16) contained multilineage (myeloid and B lymphoid) EGFP+ human cells composing as much as 59% of the graft. Half of these mice received a limiting dose of SRC, suggesting that the marked cells were derived from a single transduced SRC. Surprisingly, these culture conditions produced a large expansion (166-fold) of cells with the CD34+CD38− phenotype (n = 20). However, there was no increase in SRC numbers, indicating dissociation between the CD34+CD38− phenotype and SRC function. The underlying mechanism involved apparent downregulation of CD38 expression within a population of cultured CD34+CD38+ cells that no longer contained any SRC function. These results suggest that the relationship between stem cell function and cell surface phenotype may not be reliable for cultured cells. (Blood. 2000;95:102-110)

Expansion of human cord blood CD34+CD38−cells in ex vivo culture during retroviral transduction without a corresponding increase in SCID repopulating cell (SRC) frequency: dissociation of SRC phenotype and function

Current procedures for the genetic manipulation of hematopoietic stem cells are relatively inefficient due, in part, to a poor understanding of the conditions for ex vivo maintenance or expansion of stem cells. We report improvements in the retroviral transduction of human stem cells based on the SCID-repopulating cell (SRC) assay and analysis of Lin− CD34+CD38−cells as a surrogate measure of stem cell function. Based on our earlier study of the conditions required for ex vivo expansion of Lin−CD34+ CD38− cells and SRC, CD34+–enriched lineage–depleted umbilical cord blood cells were cultured for 2 to 6 days on fibronectin fragment in MGIN (MSCV-EGFP-Neo) retroviral supernatant (containing 1.5% fetal bovine serum) and IL-6, SCF, Flt-3 ligand, and G-CSF. Both CD34+CD38− cells (20.8%) and CFC (26.3%) were efficiently marked. When the bone marrow of engrafted NOD/SCID mice was examined, 75% (12/16) contained multilineage (myeloid and B lymphoid) EGFP+ human cells composing as much as 59% of the graft. Half of these mice received a limiting dose of SRC, suggesting that the marked cells were derived from a single transduced SRC. Surprisingly, these culture conditions produced a large expansion (166-fold) of cells with the CD34+CD38− phenotype (n = 20). However, there was no increase in SRC numbers, indicating dissociation between the CD34+CD38− phenotype and SRC function. The underlying mechanism involved apparent downregulation of CD38 expression within a population of cultured CD34+CD38+ cells that no longer contained any SRC function. These results suggest that the relationship between stem cell function and cell surface phenotype may not be reliable for cultured cells. (Blood. 2000;95:102-110)

Ex Vivo Generation of CD34+ Cells From CD34− Hematopoietic Cells

The human Lin−CD34− cell population contains a newly defined class of hematopoietic stem cells that reconstitute hematopoiesis in xenogeneic transplantation systems. We therefore developed a culture condition in which these cells were maintained and then acquired CD34 expression and the ability to produce colony-forming cells (CFC) and SCID-repopulating cells (SRCs). A murine bone marrow stromal cell line, HESS-5, supports the survival and proliferation of Lin−CD34− cells in the presence of fetal calf serum and human cytokines thrombopoietin, Flk-2/Flt-3 ligand, stem cell factor, granulocyte colony-stimulating factor, interleukin-3, and interleukin-6. Although Lin−CD34− cells do not initially form any hematopoietic colonies in methylcellulose, they do acquire the colony-forming ability during 7 days of culture, which coincides with their conversion to a CD34+ phenotype. From 2.2% to 12.1% of the cells became positive for CD34 after culture. The long-term multilineage repopulating ability of these cultured cells was also confirmed by transplantation into irradiated NOD/SCID mice. These results represent the first in vitro demonstration of the precursor of CD34+ cells in the human CD34− cell population. Furthermore, the in vitro system we reported here is expected to open the way to the precise characterization and ex vivo manipulation of Lin−CD34− hematopoietic stem cells.

Ex Vivo Generation of CD34+ Cells From CD34− Hematopoietic Cells

The human Lin−CD34− cell population contains a newly defined class of hematopoietic stem cells that reconstitute hematopoiesis in xenogeneic transplantation systems. We therefore developed a culture condition in which these cells were maintained and then acquired CD34 expression and the ability to produce colony-forming cells (CFC) and SCID-repopulating cells (SRCs). A murine bone marrow stromal cell line, HESS-5, supports the survival and proliferation of Lin−CD34− cells in the presence of fetal calf serum and human cytokines thrombopoietin, Flk-2/Flt-3 ligand, stem cell factor, granulocyte colony-stimulating factor, interleukin-3, and interleukin-6. Although Lin−CD34− cells do not initially form any hematopoietic colonies in methylcellulose, they do acquire the colony-forming ability during 7 days of culture, which coincides with their conversion to a CD34+ phenotype. From 2.2% to 12.1% of the cells became positive for CD34 after culture. The long-term multilineage repopulating ability of these cultured cells was also confirmed by transplantation into irradiated NOD/SCID mice. These results represent the first in vitro demonstration of the precursor of CD34+ cells in the human CD34− cell population. Furthermore, the in vitro system we reported here is expected to open the way to the precise characterization and ex vivo manipulation of Lin−CD34− hematopoietic stem cells.

Thymic Repopulation by CD34+ Human Cord Blood Cells After Expansion in Stroma-Free Culture

Thymic repopulation by transplanted hematopoietic progenitor cells (HPC) is likely to be important for long-term immune reconstitution and for successful gene therapy of diseases affecting the T-cell lineage. However, the T-cell progenitor potential of HPC, cultured in vitro for cell number expansion and gene transfer remains largely unknown. Here, we cultured highly purified human umbilical cord blood (CB) CD34+CD38− or CD34+CD38+ cells for up to 5 weeks in stroma-free cultures supplemented with various combinations of the cytokines thrombopoietin (TPO), stem cell factor (SCF), flt3/flk-2 ligand (FL), interleukin-3 (IL-3), and IL-6 and investigated thymus-repopulating ability of expanded cells in vitro and in vivo. After up to 5 weeks of culture in IL-3 + SCF + IL-6 or TPO + FL + SCF supplemented medium, the progeny of CD34+CD38− CB cells generated T cells and natural killer cells in the thymus. Limiting dilution experiments demonstrated increase in the number of T-cell progenitors during culture. After 3 weeks of culture, gene marked CD34+CD38− CB cells injected in the human thymus fragment transplanted in severe combined immunodeficient (SCID) mice (SCID-hu) generated thymocytes expressing the retroviral encoded marker gene GFP in vivo. Thus, our results show that the progeny of CD34+CD38− CB cells cultured for extensive periods, harbor thymus-repopulating cells that retain T-cell progenitor potential after expansion and gene transfer.

Thymic Repopulation by CD34+ Human Cord Blood Cells After Expansion in Stroma-Free Culture

Thymic repopulation by transplanted hematopoietic progenitor cells (HPC) is likely to be important for long-term immune reconstitution and for successful gene therapy of diseases affecting the T-cell lineage. However, the T-cell progenitor potential of HPC, cultured in vitro for cell number expansion and gene transfer remains largely unknown. Here, we cultured highly purified human umbilical cord blood (CB) CD34+CD38− or CD34+CD38+ cells for up to 5 weeks in stroma-free cultures supplemented with various combinations of the cytokines thrombopoietin (TPO), stem cell factor (SCF), flt3/flk-2 ligand (FL), interleukin-3 (IL-3), and IL-6 and investigated thymus-repopulating ability of expanded cells in vitro and in vivo. After up to 5 weeks of culture in IL-3 + SCF + IL-6 or TPO + FL + SCF supplemented medium, the progeny of CD34+CD38− CB cells generated T cells and natural killer cells in the thymus. Limiting dilution experiments demonstrated increase in the number of T-cell progenitors during culture. After 3 weeks of culture, gene marked CD34+CD38− CB cells injected in the human thymus fragment transplanted in severe combined immunodeficient (SCID) mice (SCID-hu) generated thymocytes expressing the retroviral encoded marker gene GFP in vivo. Thus, our results show that the progeny of CD34+CD38− CB cells cultured for extensive periods, harbor thymus-repopulating cells that retain T-cell progenitor potential after expansion and gene transfer.

Ectopic haematopoiesis in the mouse: roles of stroma and cytokines in granulocytopoiesis in in vivo diffusion chamber cultures

We have examined a possible role of two different types of irradiated stromal cells, i.e. murine bone marrow (BM) stromal cells and stromal cell line MS-5R, when cocultured with murine blood-borne progenitors or sorted Lin- Sca-1+ bone marrow cells in vivo in peritoneal diffusion chambers (DC). Retrieval and quantification of the cultured cells were performed after 4, 7, and 14 d. Granulocyte and/or macrophage colony-forming cells (G/M-CFC) were enumerated in subcultures from the DC. G/M-CFC production was not enhanced in the stroma-contact cultures, in comparison with the standard stroma-non-contact cultures, but early granulocytopoiesis was stimulated. Perturbation of the humoral environment of DC was investigated in a number of ways, for example with continuous infusion of rhG-CSF from a subcutaneous implanted minipump to DC host mice, with DC host mice carrying a transplantable leukaemia, secreting interleukin 3 (IL-3), and with injections of various cytokines. None of these interventions sustained the expansion of the G/M-CFC population. In conclusion, for ectopic haematopoiesis to take place, several requirements must be met. Relevant stromal cells apparently affect haematopoiesis both via direct cell-cell interactions and via humoral mediators (viz. cytokines) which they secrete.

Hematopoietic compartment of Fanconi anemia group C null mice contains fewer lineage-negative CD34+ primitive hematopoietic cells and shows reduced reconstruction ability

Fanconi anemia (FA) is a complex recessive genetic disease that causes bone marrow failure in children. The mechanism by which the gene for FA group C (Fancc) impinges on the normal hematopoietic program is unknown. Here we demonstrate that the bone marrow from Fancc-/- mice have reduced ability for primary and secondary long-term reconstitution of myeloablated recipients compared to wild-type or heterozygous mice, indicating that the Fancc gene product is required for the maintenance of normal numbers of hematopoietic stem cells. Long-term and secondary transplant studies suggested that there also were qualitative changes in their developmental potential. Consistent with the reduction in reconstitution, flow cytometric analysis of the primitive subfractions of hematopoietic cells obtained from the bone marrow of Fancc -/- mice demonstrated that they contained 40 to 70% fewer lineage-negative (Lin-)Thy1.2-/lowScal(+) c-Kit(+)CD34+ cells compared to controls. In contrast, the number of Lin Thy1.2-/ lowScal(+)c-Kit CD34(-)cells was comparable to that of wild-type mice. The differential behavior of Lin(-)Thy1.2-/lowScal+c-Kit+CD34+ and Lin(-)Thy1.2-/lowScal(+)c-Kit CD34 subfractions also was observed in mice treated with the DNA cross-linking agent mitomycin C(MMC). Fancc-/- mice treated with MMC had an 92% reduction of CD34 cells as compared to Fancc+/+ mice. The number of CD34 cells only was reduced about 20%. These results suggest that the Fancc gene may act at a stage of primitive hematopoietic cell development identified by CD34 expression.

Comparison of hematopoietic activities of human bone marrow and umbilical cord blood CD34 positive and negative cells

Although the hematopoietic activities of human CD34+ bone marrow (BM) and cord blood (CB) cells have been well characterized, the phenotype of nonobese-diabetic severe combined immunodeficient (NOD/SCID) mice repopulating cells (SRCs) in CB and BM has not yet been fully examined. To address this issue, various hematopoietic activities were compared in terms of total and CD34+ CB and BM cells. Clonal culture of fluorescence-activated cell sorter (FACS) CD34+ CB and BM cells revealed a higher incidence of colony-forming cells with greater proliferation capacity in CB over BM CD34+ cells. CB CD34+ cells also demonstrated higher secondary plating efficiency over BM cells. In addition, we demonstrated that mice transplanted with CB mononuclear cells (MNCs) showed significantly higher levels of chimerism than those transplanted with BM MNCs. However, recipients of FACS-sorted CD34+ CB cells showed significantly lower levels of chimerism than those that received total CB MNCs, suggesting a role of facilitating cells in the CD34- cell population. To further analyze the role of CD34- cells, the NOD/SCID repopulating ability of FACS-sorted CB CD34-c-kit+Lin- and CD34-c-kit-Lin- cells were examined. However, SRCs were not detected in those cells. Taken together, these data suggest that CB is a better source of hematopoietic stem cells and that there are cells in the CD34- fraction that facilitate repopulation of hematopoiesis in the NOD/SCID environment.

Human hematopoietic stem/progenitor cells generate CD5+ B lymphoid cells in NOD/SCID mice

The nonobese diabetic/severe combined immunodeficient (NOD/SCID) xenotransplantation model is increasingly utilized to study both human lymphohematopoietic stem/progenitor cells and committed cell types. Human B lymphoid cells develop and proliferate in this model. We found high numbers of CD19+CD5+ B lymphoid cells in the bone marrows and spleens of NOD/SCID mice transplanted with human CD34+ stem/progenitor cells. The CD5+ cells accounted for a particularly large percentage of the B lymphoid cells in the spleens of chimeras analyzed three months after transplantation. CD19+CD5+ cells from all the analyzed chimeras coexpressed HLA-DR, surface IgM, CD20, CD38, CD43, and CD45. However, CD19+CD5+ cells were negative for kappa light chain, CD10, CD11a, CD11b, CD15, CD21, CD22, CD23, CD25, CD34, CD35, CD44, CD62L, CD69, and CD71. Cell surface expression of the lambda light chain, surface IgD, CD9, and CD40 antigens was detected in some but not all chimeras. Thus, the CD19+CD5+ cell population detected in our study has the phenotype of previously described CD5+ B lymphoid cells in humans and other species. The origin and role of the B lymphoid cells which express CD5 cell surface glycoprotein are poorly understood. The malignant cells in B lymphoid chronic lymphocytic leukemia express CD5, and the numbers of CD5+ B lymphoid cells are elevated in several autoimmune conditions. The human-NOD/SCID chimera system may provide an in vivo model to investigate the maturation and development of this cryptic human CD5+ B lymphoid cell subpopulation.

Direct Evidence for Multiple Self-Renewal Divisions of Human In Vivo Repopulating Hematopoietic Cells in Short-Term Culture

Recently, culture conditions that stimulate the proliferation of primitive hematopoietic cells defined by various phenotypic and functional endpoints in vitro have been identified. However, evidence that they support a high probability of self-renewal leading to a large net expansion in vitro of transplantable cells with lympho-myeloid repopulating ability has been more difficult to obtain. The present study was designed to investigate whether the low overall expansion of human repopulating hematopoietic cells seen in vitro reflects a selective unresponsiveness of these rare cells to the growth factors currently used to stimulate them or, alternatively, whether they do proliferate in vitro but lose engrafting potential. For this, we used a high-resolution procedure for tracking and reisolating cells as a function of their proliferation history based on the loss of cellular fluorescence after staining with (5- and 6-) carboxyfluorescein diacetate succinimidyl ester. The results show that the vast majority of long-term culture-initiating cells and in vivo lympho-myeloid competitive repopulating units present in 5-day suspension cultures initiated with CD34+ human cord blood and fetal liver cells are the progeny of cells that have divided at least once in response to stimulation by interleukin-3, interleukin-6, granulocyte colony-stimulating factor, Steel factor, and Flt3-ligand. Thus, most human repopulating cells from these two sources are stimulated to undergo multiple divisions under currently used short-term suspension culture conditions and a proportion of these retain engraftment potential.

Immunodeficient mice as models of human hematopoietic stem cell engraftment

The past year has brought forth some exciting developments in the use of murine xenotransplantation systems to study the biology and transduction of human hematopoietic stem cells. The effects of cytokines have been studied by injection into the mice or by treatment of the cell inoculum prior to injection. The importance of the cell cycle and integrin expression has been evaluated. New methods of gene therapy have been tested in xenograft models - including cell cycle manipulation and a promising new lentiviral vector system, based on HIV.

Rapid Differentiation of a Rare Subset of Adult Human Lin−CD34−CD38− Cells Stimulated by Multiple Growth Factors In Vitro

Recently, several reports of lineage-negative (lin−) CD34− cells with in vivo hematopoietic activity have focused interest on the properties and growth factor response characteristics of these cells. We have now identified a combination of 5 growth factors that are necessary and sufficient to stimulate a marked mitogenic and differentiation response by a subset of human lin−CD34−CD38− cells present in normal adult human marrow and granulocyte colony-stimulating factor (G-CSF)–mobilized blood. Less than 0.1% of the cells in highly purified (including doubly sorted) lin−CD34−CD38− cells from these 2 sources formed colonies directly in semisolid medium or generated such cells after 6 weeks in long-term culture. Nevertheless, approximately 1% of the same lin−CD34−CD38− cells were able to proliferate rapidly in serum-free liquid suspension cultures containing human flt-3 ligand, Steel factor, thrombopoietin, interleukin-3 (IL-3), and hyper–IL-6 to produce a net 28- ± 8-fold increase in total cells within 10 days. Of the cells present in these 10-day cultures, 5% ± 2% were CD34+ and 2.5% ± 0.9% were erythroid, granulopoietic, megakaryocytopoietic, or multilineage colony-forming cells (CFC) (13 ± 7 CFC per lin−CD34−CD38− pre-CFC). In contrast to lin−CD34+CD38−cells, this response of lin−CD34−CD38− cells required exposure to all of the 5 growth factors used. Up to 1.7 × 105 lin−CD34− adult marrow cells failed to engraft sublethally irradiated NOD/SCID-β2M−/− mice. These studies demonstrate unique properties of a rare subset of lin−CD34−CD38− cells present in both adult human marrow and mobilized blood samples that allow their rapid proliferation and differentiation in vitro within an overall period of 3 to 4 weeks. The rapidity of this response challenges current concepts about the normal duration and coordinated control of these processes in adults.

Rapid Differentiation of a Rare Subset of Adult Human Lin−CD34−CD38− Cells Stimulated by Multiple Growth Factors In Vitro

Recently, several reports of lineage-negative (lin−) CD34− cells with in vivo hematopoietic activity have focused interest on the properties and growth factor response characteristics of these cells. We have now identified a combination of 5 growth factors that are necessary and sufficient to stimulate a marked mitogenic and differentiation response by a subset of human lin−CD34−CD38− cells present in normal adult human marrow and granulocyte colony-stimulating factor (G-CSF)–mobilized blood. Less than 0.1% of the cells in highly purified (including doubly sorted) lin−CD34−CD38− cells from these 2 sources formed colonies directly in semisolid medium or generated such cells after 6 weeks in long-term culture. Nevertheless, approximately 1% of the same lin−CD34−CD38− cells were able to proliferate rapidly in serum-free liquid suspension cultures containing human flt-3 ligand, Steel factor, thrombopoietin, interleukin-3 (IL-3), and hyper–IL-6 to produce a net 28- ± 8-fold increase in total cells within 10 days. Of the cells present in these 10-day cultures, 5% ± 2% were CD34+ and 2.5% ± 0.9% were erythroid, granulopoietic, megakaryocytopoietic, or multilineage colony-forming cells (CFC) (13 ± 7 CFC per lin−CD34−CD38− pre-CFC). In contrast to lin−CD34+CD38−cells, this response of lin−CD34−CD38− cells required exposure to all of the 5 growth factors used. Up to 1.7 × 105 lin−CD34− adult marrow cells failed to engraft sublethally irradiated NOD/SCID-β2M−/− mice. These studies demonstrate unique properties of a rare subset of lin−CD34−CD38− cells present in both adult human marrow and mobilized blood samples that allow their rapid proliferation and differentiation in vitro within an overall period of 3 to 4 weeks. The rapidity of this response challenges current concepts about the normal duration and coordinated control of these processes in adults.

KDR receptor: a key marker defining hematopoietic stem cells

Studies on pluripotent hematopoietic stem cells (HSCs) have been hindered by lack of a positive marker, comparable to the CD34 marker of hematopoietic progenitor cells (HPCs). In human postnatal hematopoietic tissues, 0.1 to 0.5% of CD34(+) cells expressed vascular endothelial growth factor receptor 2 (VEGFR2, also known as KDR). Pluripotent HSCs were restricted to the CD34+KDR+ cell fraction. Conversely, lineage-committed HPCs were in the CD34+KDR- subset. On the basis of limiting dilution analysis, the HSC frequency in the CD34+KDR+ fraction was 20 percent in bone marrow (BM) by mouse xenograft assay and 25 to 42 percent in BM, peripheral blood, and cord blood by 12-week long-term culture (LTC) assay. The latter values rose to 53 to 63 percent in LTC supplemented with VEGF and to greater than 95 percent for the cell subfraction resistant to growth factor starvation. Thus, KDR is a positive functional marker defining stem cells and distinguishing them from progenitors.

Isolation of primitive human hematopoietic progenitors on the basis of aldehyde dehydrogenase activity

Because hematopoietic stem cells are rich in aldehyde dehydrogenase (ALDH) activity, we developed a fluorescent substrate for ALDH, termed BODIPY aminoacetaldehyde (BAAA), and tested its potential for isolating primitive human hematopoietic cells. A population of cells with low orthogonal light scattering and bright fluorescence intensity (SSC(lo)ALDH(br) cells) could be readily fractionated from human umbilical cord blood cells costained with BAAA and the multidrug-resistance inhibitor verapamil. The SSC(lo)ALDH(br) population was depleted of lineage-committed cells, 40-90% pure for CD34(+)CD38(lo/-) cells, and enriched 50- to 100-fold for primitive hematopoietic progenitors detected in short- and long-term culture analyses. Together, these observations indicate that fractionating human hematopoietic stem cells on the basis of ALDH activity using BAAA is an effective method for isolating primitive human hematopoietic progenitors. This technique may be useful for isolating stem cells from other tissues as well.

The Soluble Interleukin-6 (IL-6) Receptor/IL-6 Fusion Protein Enhances In Vitro Maintenance and Proliferation of Human CD34+CD38−/low Cells Capable of Repopulating Severe Combined Immunodeficiency Mice

In vitro maintenance and proliferation of human hematopoietic stem cells is crucial for many clinical applications. Early hematopoietic cells express low levels of FLT-3 and c-kit receptors, as well as the interleukin-6 (IL-6) receptor signal transducing element, gp130, but do not express IL-6 receptor itself. Therefore, we have attempted to maintain human cord blood or bone marrow CD34+ cells ex vivo in serum-free cultures containing stem cell factor (SCF) and FLT-3 ligand (FL) alone or together with a new recombinant molecule of soluble IL-6 receptor fused to IL-6 (IL6RIL6 chimera). The effect of IL6RIL6 chimera on the proliferation and differentiation of CD34+ cells was compared with that of each chimera component added separately. The engraftment potential of in vitro-cultured cells was determined using our recently established functional in vivo assay for primitive human severe combined immunodeficiency (SCID)-repopulating cells (SRC). We report here that IL6RIL6 chimera induced significantly higher levels of progenitors and SRC compared with SCF + FL alone or together with IL-6 and soluble IL-6 receptor. IL6RIL6 chimera prolonged in vitro maintenance of SRC for up to 14 days. Stimulation of CD34+CD38−/low enriched cells with IL6RIL6 chimera maintained the early CD34+CD38−/lowcell subpopulation, which could be detected in vitro for up to 14 days. Moreover, IL6RIL6 chimera preferentially stimulated the growth of early CD34+38−/low cells, resulting in significantly higher levels of progenitors compared with more mature CD34+38+ cells. Taken together, these findings demonstrate the importance of IL6RIL6 chimera in stimulating the proliferation of early CD34+· CD38−gp130+IL-6R−cells in vitro and extended maintenance of progenitors and SRC.

Hematopoietic reconstitution of syngeneic mice with a peripheral blood-derived, monoclonal CD34-, Sca-1+, Thy-1(low), c-kit+ stem cell line

Previous work had revealed that a CD34- fibroblast-like cell is the earliest hematopoietic progenitor population. This cell type is able to differentiate into hematopoietic progeny of all lineages and circulates in the peripheral blood, from where it can be isolated by IL-6-mediated plastic adherence. We isolated peripheral blood-derived mononuclear cells (MNC) from male CBA mice and established in vitro a fibroblast-like, adherent growing cell layer. Cells were immortalized by SV-40 transfection for cellular cloning. Monoclonal fibroblast-like cell clones were established, and the surface expression of early stem cell markers was determined by flow cytometry. Clones were CD34-, Sca-1+, Thy-1(low), and c-kit+. Lethally irradiated female CBA mice were successfully transplanted with a fibroblast-like cell clone, R-M26/2-1. After syngeneic transplantation, peripheral blood counts were back to normal in transplanted mice on days 15-20, and fluorescence in situ hybridization (FISH) revealed the sole presence of male hematopoietic cells in the BM of female recipients at weeks 7, 9, 11, and 16 after transplantation. Immunohistochemistry for the expression of CD34, Sca-1, Thy-1, and c-kit showed the presence of the phenotype of the transplanted stem cell clone along the bone spicules in the marrow cavity, giving rise to HPC of all lineages. In summary, we have shown that a CD34-, Sca-1+, Thy-1(low), and c-kit+ fibroblast-like cell is consistent with the phenotype of the earliest hematopoietic and repopulating stem cell and can be isolated from peripheral blood cells.

Characterization and retroviral transduction of an early human lymphomyeloid precursor assayed in nonswitched long-term culture on murine stroma

In the hierarchy of human hematopoietic progenitors, long-term culture-initiating cells (LTC-IC) and extended LTC-IC belong to the earliest cell populations that can be assayed in vitro. We report the identification of a multipotential lymphomyeloid progenitor detected in a nonswitch culture system. We observed the emergence of CD33+ myeloid and CD19+ B-lymphoid cells following plating of lineage-depleted (Lin-) CD34 -enriched or purified CD34+ CD38- cord blood cells on MS-5 stroma in the absence of exogenous cytokines. Both CD19+ CD20- pro-B and CD19+ CD20+ pre-B lymphocytes coexist with myeloid cells in long-term culture. A limiting dilution approach was used to show that a single CD34+ CD38- cell can generate lymphomyeloid progeny in conventional (5-week) and extended (10-week) cultures. Most of the clones in long-term culture or extended long-term culture contained not only lymphoid and myeloid cells, but also myeloid clonogenic progenitors. A high proportion of CD34+ CD38- cells gave rise to lymphomyeloid clones after 5 and 10 weeks of culturing (up to 48% and 16%, respectively), which distinguishes the assay reported here from those using switch culture conditions. We performed retroviral gene transfer experiments involving 1-3 days of exposure of Lin CD34+ -enriched cells to virus encoding enhanced green fluorescent protein. Monitoring of gene transfer efficiency into LTC-IC by enhanced green fluorescent protein fluorescence showed that it is possible to achieve marking of lymphomyeloid LTC-IC, albeit to a lesser extent than myeloid-restricted LTC-IC.

Homing and mobilization in the stem cell niche

All mature blood cells are derived from the haemopoietic stem cell (HSC). In common with all other haemopoietic cells, stem cells are mobile, and it is this property of mobility that has allowed bone marrow transplantation to become a routine clinical option. Successful transplantation requires haemopoietic stem cells to home to the bone marrow, leave the peripheral circulation and become stabilized in regulatory niches in the extravascular space of the bone marrow cavity. This homing and tethering process is reversible - haemopoietic stem cells can be released from their bone marrow tethering through changes in molecular interactions, which are also important in homing following transplantation. The molecular mechanisms regulating this two-way flow of stem cells are beginning to be elucidated, and much recent data has emerged that sheds light on the processes and molecules involved in these complex physiological events. This article reviews current knowledge of the adhesive, homing and proliferative influences acting on HSCs and progenitor cells.

Functional activity of murine CD34+ and CD34- hematopoietic stem cell populations

The transmembrane glycoprotein CD34 is expressed on human hematopoietic stem cells and committed progenitors in the bone marrow, and CD34-positive selection currently is used to isolate bone marrow repopulating cells in clinical transplantation protocols. Recently, CD34- hematopoietic stem cells were described in both humans and mice, and it was suggested that CD34+ murine bone marrow cells may lack long-term reconstituting ability. In this study, the long-term repopulating ability of CD34+Lin- vs CD34-Lin- cells was compared directly using syngeneic murine bone marrow transplantation. Highly purified populations of CD34+Lin- and CD34-Lin- cells each are able to reconstitute bone marrow, confirming that both populations contain hematopoietic stem cells; however, the number of hematopoietic stem cells in the CD34+Lin- fraction is approximately 100-fold greater than the number in the CD34-Lin- fraction. In competitive repopulation experiments, CD34+ stem cells are better able to engraft the bone marrow than are CD34- cells. CD34+Lin- cells provide both short- and long-term engraftment, but the CD34-Lin- cells are capable of only long-term engraftment. Ex vivo, the CD34+Lin- stem cells expand over 3 days in culture and maintain the ability to durably engraft animals in a serial transplant model. In contrast, when CD34-Lin- cells are cultured using the same conditions ex vivo, the cell number decreases, and the cells do not retain the ability to repopulate the bone marrow. Thus, the CD34+Lin- and CD34-Lin- cells constitute two functionally distinct populations that are capable of long-term bone marrow reconstitution.

Optimization of retroviral-mediated gene transfer to human NOD/SCID mouse repopulating cord blood cells through a systematic analysis of protocol variables

Retroviral transduction of human hematopoietic stem cells is still limited by lack of information about conditions that will maximize stem cell self-renewal divisions in vitro. To address this, we first compared the kinetics of entry into division of single human CD34+CD38- cord blood (CB) cells exposed in vitro to three different flt3-ligand (FL)-containing cytokine combinations. Of the three combinations tested, FL + hyperinterleukin 6 (HIL-6) yielded the least clones and these developed at a slow rate. With either FL + Steel factor (SF) + HIL-6 + thrombopoietin (TPO) or FL + SF + interleukin 3 (IL-3) + IL-6 + granulocyte-colony-stimulating factor (G-CSF), >90% of the cells that formed clones within 6 days undertook their first division within 4 days, although not until after 24 hours. These latter two, more stimulatory, cytokine combinations then were used to assess the effect of duration of cytokine exposure on the efficiency of transducing primitive CB cells with a gibbon ape leukemia virus-pseudotyped murine retroviral vector containing the enhanced green fluorescent protein (GFP) cDNA and the neomycin resistance gene. Fresh lin- CB cells exposed once to medium containing this virus plus cytokines on fibronectin-coated dishes yielded 23% GFP+ CD34+ cells and 52-57% G418-resistant CFC when assessed after 2 days. Prestimulation of the target cells (before exposing them to virus) with either the four or five cytokine combination increased their susceptibility. In both cases, the effect of prestimulation assessed using the same infection protocol was maximal with 2 days of prestimulation and resulted in 47-54% GFP+ CD34+ cells and 67-69% G418-resistant CFC. Repeated daily addition of new virus (up to three times), with assessment of the cells 2 days after the last addition of fresh virus, gave only a marginal improvement in the proportion of transduced CD34+ cells and CFC, but greatly increased the proportion of transduced LTC-IC (from 40% to >99%). Transplantation of lin- CB cells transduced using this latter 6-day protocol into NOD/SCID mice yielded readily detectable GFP+ cells in 10 of 11 mice that were engrafted with human cells. The proportion of the regenerated human cells that were GFP+ ranged from 0.2-72% in individual mice and included both human lymphoid and myeloid cells in all cases. High-level reconstitution with transduced human cells was confirmed by Southern blot analysis. These findings demonstrate that transplantable hematopoietic stem cells in human CB can be reproducibly transduced at high efficiency using a 6-day period of culture in a retrovirus-containing medium with either FL + SF + HIL-6 + TPO or FL + SF + IL-3 + IL-6 + G-CSF in which virus is added on the third, fourth, and fifth day.

Absence of CD34 on some human SCID-repopulating cells

The availability of in vivo repopulation assays has greatly aided the study of human hematopoietic stem cells. Here, I shall review recent data that has identified a novel class of human repopulating cells that do not express classical stem cell markers including CD34 but still retain the ability to repopulate nonobese diabetic/severe combined immunodeficient (NOD/SCID) mice.

Defining optimum conditions for the ex vivo expansion of human umbilical cord blood cells. Influences of progenitor enrichment, interference with feeder layers, early-acting cytokines and agitation of culture vessels

Ex vivo expansion of human umbilical cord blood cells (HUCBC) is explored by several investigators to enhance the repopulating potential of HUCBC. We performed experiments using either Ficoll-separated or CD34+-selected HUCBC from the same donation in serum-free medium. CD34-purified HUCBC were cultured on either human umbilical vein endothelial cells (HUVEC) or irradiated bone marrow-derived stroma cells (BMSC) with addition of different cytokines. In addition, we tested the expansion of HUCBC in culture vessels with continuous rotation. CD34 enrichment led to a significant increase in the expansion factor of CD34+ cells compared with unmanipulated HUCBC. BMSC were more efficient in amplifying early progenitors than HUVEC. Optimum results were reached by a combination of SCF, FLT-3L at 300 ng/ml and IL-3 at 50 ng/ml. No significant improvement in the expansion of CD34+/38- primitive progenitors could be obtained with other combinations. Addition of megakaryocyte-derived growth and development factor to each growth factor cocktail improved the expansion results. Continuous rotation of culture vessels did not ameliorate the expansion rate of the analyzed subsets. Culture conditions separating stroma and HUCBC by a semipermeable membrane improved the expansion factors of CD34+, CD34+/38-, and CD34+/41+ cells and CFU-GM compared with contact cultures. These data might be useful when designing culture systems for clinical scale ex vivo expansion of HUCBC.

Cell analysis for hematopoietic stem/progenitor cell transplantation

Cytometric analysis has become an important aspect in the quality control of cells in all phases of hematopoietic cell transplantation. In the stage of donor conditioning the counting of stem and progenitor cells is important and several reliable single platform tests for CD34+ cells have become available recently. It has been shown, that the count of certain subsets of CD34 may predict best time for harvesting stem cells better than just CD34. In many cases manipulation of the cell sample after collection from the donor is necessary before the cells are adequate for transplantation. Characterization of the resulting cell preparations requires reliable quantitative analysis of a variety of cell types like the enumeration of T-cells at the level of one in ten thousand for some allogeneic transplantations. It is discussed how these clinical requirements will need a refinement of cytometric procedures to achieve adequate clinical decisions.

Transduction of human CD34+ cells that mediate long-term engraftment of NOD/SCID mice by HIV vectors

Efficient gene transfer into human hematopoietic stem cells (HSCs) is an important goal in the study of the hematopoietic system as well as for gene therapy of hematopoietic disorders. A lentiviral vector based on the human immunodeficiency virus (HIV) was able to transduce human CD34+ cells capable of stable, long-term reconstitution of nonobese diabetic/severe combined immunodeficient (NOD/SCID) mice. High-efficiency transduction occurred in the absence of cytokine stimulation and resulted in transgene expression in multiple lineages of human hematopoietic cells for up to 22 weeks after transplantation.

Transduction of CD34(+) and CD34(-)/lin(-) hemopoietic progenitors by lentivirus vectors

BACKGROUND

While hemopoietic stem cells have been thought to reside predominantly in the CD34(+) population, recent data suggests that repopulating cells may, in fact, also reside in the lin(-)/CD34(-) population. Transduction of both these populations by murine retroviral vectors is limited by quiescence of hemopoietic stem cells.

METHODS

We therefore sought to transduce these populations using a VSV-G pseudotyped, HIV-based, human lentiviral vector, encoding eGFP. CD34(+) cells and lin(-)/CD34(-) cells were selected from the same BM samples by immunomagnetic beads (StemSep) to deplete lineage-positive cells and by CD34 selection columns (Miltenyi) to separate CD34(+) and CD34(-) populations. We transduced target cells, with or without prestimulation with cytokines, using conventional suspension culture, or fibronectin plates, or flow-through transduction. Transduction efficiency was analyzed by flow cytometry and clonogenic assay.

RESULTS

We found that transduction on fibronectin plates was more efficient than flow-through transduction, or suspension cultures, for both cell populations. Mean transduction rates on fibronectin plates, analyzed by flow cytometry, were 14% and 5% for CD34(+) cells and lin(-)/CD34(-) cells respectively, without prestimulation, and 31% and 20% with prestimulation. By contrast, a murine retroviral vector transduces CD34(+) cells with lower efficiency (mean 16.1% with prestimulation) and does not induce any significant transduction of the CD34(-)/lin(-) population (mean < 2%). When lentiviral transduction was assayed in short- and long-term clonogenic assays there was minimal transduction of CD34 cells without prestimulation, increasing to 20% with prestimulation.

DISCUSSION

Lentiviral eGFP vectors can transduce hematopoietic progenitors effectively and efficiency is improved by cytokine prestimulation and the use of fibronectin. Moreover, the human viral vectors can transduce a candidate stem-cell population that is resistant to murine retroviral transduction.

Successful transfer of ADA gene in vitro into human peripheral blood CD34+ cells by transfecting EBV-based episomal vectors

We report a novel non-viral system for transfecting human immature hematopoietic cells in vitro. Epstein-Barr virus (EBV)-based episomal vectors carrying human adenosine deaminase (ADA) gene cDNA were transfected by electroporation into human peripheral blood (PB) CD34+ cells. The transgene-specific mRNA were detected from 37 to 100% of CFU-c (colony forming unit in culture) colonies derived from the transfected cells. A two-fold increase in enzyme activity was also found. These results indicate the successful transfer and expression of genes in human immature hematopoietic cells using the EBV-based episomal vector system.