In vitro proliferation potential of AC133 positive cells in peripheral blood

AC133 antigen is a novel marker for human hematopoietic stem/progenitor cells. In this study, we examined the expression and proliferation potential of AC133(+) cells obtained from steady-state peripheral blood (PB). The proportion of AC133(+) cells in the CD34(+) subpopulation of steady-state PB was significantly lower than that of cord blood (CB), although that of cytokine-mobilized PB was higher than that of CB. The proliferation potential of AC133(+)CD34(+) and AC133(-)CD34(+) cells was examined by colony-forming analysis and analysis of long-term culture-initiating cells (LTC-IC). Although the total number of colony-forming cells was essentially the same in the AC133(+)CD34(+) fraction as in the AC133(-)CD34(+) fraction, the proportion of LTC-IC was much higher in the AC133(+)CD34(+) fraction. Virtually no LTC-IC were detected in the AC133(-)CD34(+) fraction. In addition, the features of the colonies grown from these two fractions were quite different. Approximately 70% of the colonies derived from the AC133(+)CD34(+) fraction were granulocyte-macrophage colonies, whereas more than 90% of the colonies derived from the AC133(-)CD34(+) fraction were erythroid colonies. Furthermore, an ex vivo expansion study observed expansion of colony-forming cells only in the AC133(+)CD34(+) population, and not in the AC133(-)CD34(+) population. These findings suggest that to isolate primitive hematopoietic cells from steady-state PB, selection by AC133 expression is better than selection by CD34 expression.     

Murine side population cells contain cobblestone area-forming cell activity in mobilized blood

Primitive hematopoietic stem cells (HSCs) can be purified from murine bone marrow by sorting Hoechst 33342-effluxing side population (SP) cells. The aim of this study was to establish whether SP cells from peripheral blood contain primitive HSCs and whether this is altered in mice following mobilization. SP cells were analyzed and isolated from bone marrow and blood of mice after mobilization; the HSC content of isolated SP cells was determined through surrogate cobblestone area-forming cell (CAFC) assays. SP cells in normal blood were not found in the high Hoechst dye effluxing portion of the SP tail, did not express the stem cell markers c-Kit and CD34, and did not have measurable CAFC activity. In contrast, SP cells in mobilized blood expressed both stem cell markers, contained cells in the high dye efflux portion of the SP tail, and displayed significant day- 28 to day-35 CAFC activity with 165- to 334-fold enrichment. In comparison to mobilized blood SP cells, normal marrow SP cells contained a higher proportion of cells expressing c-Kit and CD34 and had a greater percentage of cells in the high Hoechst dye-effluxing portion of the SP tail. Analysis of SP cells in the bone marrow after mobilization revealed a decrease in the frequency of SP cells, in expression of c-Kit and Sca+ CD34(+)/CD34(-), and in day-7 to day-35 CAFC activity, consistent with mobilization into blood. We conclude that murine SP cells mobilized into blood contain primitive hematopoietic stem cell activity (day-28 to day-35 CAFC activity). This model offers a means to study the mechanisms of mobilization of primitive stem cells directly in a murine model.     

Microencapsulated feeder cells as a source of soluble factors for expansion of CD34(+) hematopoietic stem cells

Expansion of hematopoietic stem cells (HSCs) from cord blood is highly desired for treatment and transplantation of adult patients for hematologic diseases. For efficient proliferation of HSCs, CD34(+) cells from cord blood were co-cultured with microencapsulated murine stromal cells (HESS-5) or immortalized human mesenchymal stem cells (MSCs) in their conditioned media (CM). Bioactive substances for HSC proliferation in CM at the onset of culture are likely consumed by HSCs with time, and co-culturing with microencapsulated feeder cells ensures a continuous supply. The cell number of CD34(+) cell progeny efficiently increased under these culture conditions, and progeny were analyzed by flow cytometry, the colony assay and the cobblestone area-forming cell (CAFC) assay. Total nucleated cells and CD34(+) cell number increased 194- and 7.4-fold, respectively, in the presence of microencapsulated HESS-5 in CM. Colony forming cells and CAFCs were well maintained. The effective expansion of total cells and maintenance of primitive progenitor cells suggest that transfusion of the progeny obtained from CD34(+) cell culture with microencapsulated HESS-5 in CM could shorten the time to engraftment by bridging the pancytopenic period and support functional hematopoietic repopulation.     

Differential kinetics of primitive hematopoietic cells assayed in vitro and in vivo during serum-free suspension culture of CD34+ blood progenitor cells.

So far, blood progenitor cells (BPC) expanded ex vivo in the absence of stromal cells have not been demonstrated to reconstitute hematopoiesis in myeloablated patients. To characterize the fate of early hematopoietic progenitor cells during ex vivo expansion in suspension culture, human CD34(+)-enriched BPC were cultured in serum-free medium in the presence of FLT3 ligand (FL), stem cell factor (SCF) and interleukin 3 (IL-3). Both CD34 surface expression levels and the percentage of CD34+ cells were continuously downregulated during the culture period. We observed an expansion of colony-forming units granulocyte-macrophage (CFU-GM) and BFU-E beginning on day 3 of culture, reaching an approximate 2-log increase by days 5 to 7. Limiting dilution analysis of primitive in vitro clonogenic progenitors was performed through a week 6 cobblestone-area-forming cell (CAFC) assay, which has previously been shown to detect long-term bone marrow culture-initiating cells (LTC-IC). A maintenance or a slight (threefold) increase of week 6 CAFC/LTC-IC was found after one week of culture. To analyze the presence of BPC mediating in vivo engraftment, expanded CD34+ cells were transplanted into preirradiated NOD/SCID mice at various time points. Only CD34+ cells cultured for up to four days successfully engrafted murine bone marrow with human cells expressing myeloid or lymphoid progenitor phenotypes. In contrast, five- and seven-day expanded human BPC did not detectably engraft NOD/SCID mice. When FL, SCF and IL-3-supplemented cultures were performed for seven days on fibronectin-coated plastic, or when IL-3 was replaced by thrombopoietin, colony forming cells and LTC-IC reached levels similar to those of control cultures, yet no human cell engraftment was recorded in the mice. Also, culture in U-bottom microplates resulting in locally increased CD34+ cell density had no positive effect on engraftment. These results indicate that during ex vivo expansion of human CD34+ cells, CFC and LTC-IC numbers do not correlate with the potential to repopulate NOD/SCID mice. Our results suggest that ex vivo expanded BPC should be cultured for limited time periods only, in order to preserve bone-marrow-repopulating hematopoietic stem cells.     

Lineage-negative side-population (SP) cells with restricted hematopoietic capacity circulate in normal human adult blood: immunophenotypic and functional characterization

Side-population (SP) cells are a recently described rare cell population detected in selected tissues of various mammalian species, but not yet described in the peripheral circulation. In the present study, we have identified for the first time SP cells in lineage-negative adult human blood and have provided an extensive functional and immunophenotypic characterization of these cells. Adult peripheral blood was depleted of mature leukocyte cell types by density gradient and immunomagnetic separation. The SP cell population was identified by its characteristic Hoechst 33342 profile. Immunophenotypic analysis revealed that blood SP cells expressed high levels of CD45, CD59, CD43, CD49d, CD31, and integrin markers and lacked CD34. Highly purified SP cells were put into cobblestone area-forming cell (CAFC), long-term culture-initiating cell (LTC-IC), and liquid cell culture assays; repopulating assays were performed utilizing nonobese diabetic/severe combined immunodeficient mice. Circulating SP cells were shown to exhibit verapamil sensitivity and a low growth rate. LTC-IC, CAFC, and engraftment assays indicated that circulating SP cells had lost the multipotentiality described in murine bone marrow SP cells. However, outgrowth of mature cell types from liquid cell culture suggests the presence of common lymphoid (T and natural killer) and dendritic cell precursor(s) within circulating SP cell populations. The absence of SP cell growth in the LTC-IC, CAFC, and repopulating assays might be intrinsic to the tissue source (marrow versus blood) or species (mouse versus human) tested. Thus, human blood SP cells, although rare, may serve as a source of selected leukocyte progenitor cells. The immunophenotype of circulating SP cells may provide clues to their seeding and homing capacity.     

Bone morphogenetic protein 4 contributes to the maintenance of primitive cord blood hematopoietic progenitors in an ex vivo stroma-noncontact co-culture system

Establishment of conditions supporting hematopoietic stem cell (HSC) maintenance and expansion ex vivo is critical for wider clinical application of cord blood (CB) transplantation. AFT024 is a murine fetal liver cell line that expands primitive hematopoietic cells via a process that is not understood. Here we show that bone morphogenic protein 4 (BMP4) is produced by AFT024 and contributes significantly to the maintenance of co-cultured CB-derived primitive cells. Significant amounts of BMP4 mRNA are produced by the supportive AFT024 stromal cell line, and secreted BMP4 protein accumulates in AFT024 conditioned medium. Blockade of BMP4 activity in this coculture model using neutralizing BMP4 monoclonal antibody reduced expansion of primitive CB cells on the basis of phenotypic (CD34(+)CD38(-)) and functional criteria [long-term culture initiating cells (LTC-IC)] and significantly reduced the capacity of the cultured CB stem cells to support repopulation in the nonobese diabetic-severe combined immunodeficiency (NOD-SCID) xenograft model. Therefore, BMP4 is a key growth factor for maintenance of HSC and contributes to the unique properties of the AFT024 stromal noncontact culture.     

Gene-expression profiling of CD34+ cells from various hematopoietic stem-cell sources reveals functional differences in stem-cell activity

The replacement of bone marrow (BM) as a conventional source of stem cell (SC) by umbilical cord blood (UCB) and granulocyte-colony stimulating factor-mobilized peripheral blood SC (PBSC) has brought about clinical advantages. However, several studies have demonstrated that UCB CD34(+) cells and PBSC significantly differ from BM CD34(+) cells qualitatively and quantitatively. Here, we quantified the number of SC in purified BM, UCB CD34(+) cells, and CD34(+) PBSC using in vitro and in vivo assays for human hematopoietic SC (HSC) activity. A cobblestone area-forming cell (CAFC) assay showed that UCB CD34(+) cells contained the highest frequency of CAFC(wk6) (3.6- to tenfold higher than BM CD34(+) cells and PBSC, respectively), and the engraftment capacity in vivo by nonobese diabetic/severe combined immunodeficiency repopulation assay was also significantly greater than BM CD34(+), with a higher proportion of CD45(+) cells detected in the recipients at a lower cell dose. To understand the molecular characteristics underlying these functional differences, we performed several DNA microarray experiments using Affymetrix gene chips, containing 12,600 genes. Comparative analysis of gene-expression profiles showed differential expression of 51 genes between BM and UCB CD34(+) SC and 64 genes between BM CD34(+) cells and PBSC. These genes are involved in proliferation, differentiation, apoptosis, and engraftment capacity of SC. Thus, the molecular expression profiles reported here confirmed functional differences observed among the SC sources. Moreover, this report provides new insights to describe the molecular phenotype of CD34(+) HSC and leads to a better understanding of the discrepancy among the SC sources.     

Characterization of chemokine receptors expressed in primitive blood cells during human hematopoietic ontogeny

Chemokines are capable of regulating a variety of fundamental processes of hematopoietic cells that include proliferation, differentiation, and migration. To evaluate potential chemokine signaling pathways important to the regulation of primitive human hematopoietic cells, we examined chemokine receptor expression of highly purified subpopulations of uncommitted human blood cells. CXCR1-, CXCR2-, CXCR4-, and CCR5-expressing cells were detected by flow cytometry among human blood subsets depleted of lineage-restricted cells (Lin(-)) derived from adult bone marrow, mobilized peripheral blood, cord blood (CB), and circulating fetal blood. Although these chemokine receptors could be detected on Lin(-) cells throughout human development, only CXCR4 could be detected in CD34(-)CD38(-)Lin(-) and CD34(+)CD38(-)Lin(-) subfractions enriched for stem cell function, suggesting that independent of ontogeny, CXCR4-mediated signals are critical to primitive hematopoiesis. Distinct to other stages of human hematopoietic development, primitive CB cells expressed higher levels of CXCR1, CXCR2, CCR5, and CXCR4 on both CD34(-)CD38(-)Lin(-) and CD34(+)CD38(-)Lin(-) subsets. Isolation of these fractions revealed expression of additional chemokine receptors CCR7, CCR8, and Bonzo (STRL133), whereas BOB (GPR15) could not be detected. Our study illustrates that rare uncommitted hematopoietic cells express chemokine receptors not previously associated with primitive human blood cells. Based on these results, we suggest that signaling pathways mediated by chemokine receptors identified here may play a fundamental role in hematopoietic stem cell regulation and provide alternative receptor targets for retroviral pseudotyping for genetic modification of repopulating cells.     

Immunophenotype and functional characteristics of human primitive CD34-negative hematopoietic stem cells: the significance of the intra-bone marrow injection

The biology of hematopoietic stem cell (HSC) is a current topic of interest which has important implications for clinical HSC transplantation as well as for the basic research of HSC. The most primitive HSCs in mammals, including mice and humans, have long been believed to be CD34 antigen (Ag)-positive (CD34(+)) cells. In fact, bone marrow (BM), peripheral blood (PB), and cord blood (CB) stem cell transplantation studies indicate that a CD34(+) subpopulation in the BM, PB, or CB can provide durable long-term donor-derived lymphohematopoietic reconstitution. Therefore, CD34 Ag was used to identify/purify immature HSCs. However, Osawa et al. reported that murine long-term lymphohematopoietic reconstituting HSCs are lineage marker-negative (Lin(-)) c-kit(+)Sca-1(+)CD34-low/negative (CD34(low/-)), which are called CD34(low/-) KSL cells. Recently, human CB-derived CD34(-) HSCs, a counterpart of murine CD34(low/-) KSL cells, were successfully identified using an intra-bone marrow injection (IBMI) method. This review will update the concept of the immunophenotype and the functional characteristics of human primitive CD34(-) HSCs. In addition, the significance of the application of the IBMI technique in clinical HSC transplantation is also discussed. Recent rapid advances in understanding the biological nature of HSCs may make it possible to fully characterize the most primitive class of human HSCs in the near future.     

Hematopoietic repopulating ability of cord blood CD34(+) cells in NOD/Shi-scid mice

Although umbilical cord blood (CB) is increasingly being used as an alternative to bone marrow (BM) as a source of transplantable hematopoietic stem cells (HSC), information on the hematopoietic repopulating ability of CB HSC is still limited. We recently established a xenotransplantation system in NOD/Shi-scid mice to evaluate human stem cell activity. In the present study, we transplanted 5 to 10 x 10(4) CB CD34(+) cells into six NOD/Shi-scid mice treated with anti-asialo GM1 antiserum to investigate the hematopoietic repopulating ability of CB. The BM of all recipients contained human CD45(+) cells 10 to 12 weeks after the transplantation (43.8 +/- 17.7%). Clonal culture of the recipient BM cells revealed the formation of various types of human hematopoietic colonies, including myelocytic, erythroid, megakaryocytic, and multilineage colonies, indicating that CB HSC can differentiate into hematopoietic progenitors of various lineages. However, the extent of the differentiation and maturation differed with each lineage. CD13(+)/CD14(+)/CD33(+) myelocytic cells were mainly repopulated in BM and peripheral blood (PB). While CD41(+) megakaryocytic cells and platelets were present, few glycophorin A(+)CD71(+) or hemoglobin alpha-containing erythroid cells were detected. CD19(+) B cells were the most abundantly repopulated in NOD/Shi-scid mice, but their maturational stage differed among the hematopoietic organs. Most of the BM CD19(+) cells were immature B cells expressing CD10 but not surface immunoglobulin (Ig) M, whereas more mature CD19(+)CD10(-) surface IgM(+) B cells were predominantly present in spleen and PB. CD3(+) T cells were not detected even in the recipient thymus. The transplantation to the NOD/Shi-scid mouse may provide a useful tool for evaluating the repopulating ability of transplantable human HSC.     

培养前后脐血CD34~＋细胞在NOD/SCID鼠体内造血重建功能的比较

目的:以NOD/SCID小鼠为模型, 经半致死剂量照射后输注新鲜或培养后的造血细胞, 以比较培养前后脐血CD34 细胞的造血重建功能.方法:从新鲜脐血中分离单个核细胞(MNC), 采用干细胞因子(SCF)、血小板生成素(TPO)、Flt3配体(FL)、白细胞介素3(IL-3)和白细胞介素6(IL-6)细胞因子组合体外培养14 d.通过MiniMACS免疫磁性吸附柱从新鲜或培养后的MNC中分离CD34 细胞, 4×105个CD34 细胞和5×106CD34-细胞混合后通过尾静脉输注入NOD/SCID小鼠中.饲养过程中动态观察外周血象恢复情况, 6周后检测小鼠骨髓和脾脏细胞中人源细胞及各系造血细胞的含量.结果:体外培养MNC 14 d后, 总细胞扩增了1.78倍;细胞移植6周后, 输注新鲜和培养后造血细胞的小鼠均存活, 在小鼠骨髓和脾脏中均可检测到人源细胞及各系人源血细胞和人特异ALU基因序列, 小鼠外周血象恢复到辐照前水平.培养后CD34 细胞在小鼠体内的植入水平与新鲜CD34 细胞的相近, 而其各系人源血细胞的含量高于新鲜CD34 细胞. 结论:体外培养14 d后的CD34 细胞仍保持了体内植入和重建造血的能力, 且其多系造血重建能力优于新鲜CD34 细胞.     

Differences between peripheral blood and cord blood in the kinetics of lineage-restricted hematopoietic cells: implications for delayed platelet recovery following cord blood transplantation

Cord blood (CB) cells are a useful source of hematopoietic cells for transplantation. The hematopoietic activities of CB cells are different from those of bone marrow and peripheral blood (PB) cells. Platelet recovery is significantly slower after transplantation with CB cells than with cells from other sources. However, the cellular mechanisms underlying these differences have not been elucidated. We compared the surface marker expression profiles of PB and CB hematopoietic cells. We focused on two surface markers of hematopoietic cell immaturity, i.e., CD34 and AC133. In addition to differences in surface marker expression, the PB and CB cells showed nonidentical differentiation pathways from AC133(+)CD34(+) (immature) hematopoietic cells to terminally differentiated cells. The majority of the AC133(+)CD34(+) PB cells initially lost AC133 expression and eventually became AC133(-)CD34(-) cells. In contrast, the AC133(+)CD34(+) CB cells did not go through the intermediate AC133(-)CD34(+) stage and lost both markers simultaneously. Meanwhile, the vast majority of megakaryocyte progenitors were of the AC133(-)CD34(+) phenotype. We conclude that the delayed recovery of platelets after CB transplantation is due to both subpopulation distribution and the process of differentiation from AC133(+)CD34(+) cells.     

OP9 stroma augments survival of hematopoietic precursors and progenitors during hematopoietic differentiation from human embryonic stem cells

The cellular mechanism and target cell affected by stromal microenvironments in augmenting hematopoietic specification from pluripotent human embryonic stem cells (hESCs) has yet to be evaluated. Here, in contrast to aorta-gonad-mesonephros-derived S62 stromal cells, OP9 cells inhibit apoptosis and also augment the proliferation of hemogenic precursors prospectively isolated from human embryoid bodies. In addition, OP9 stroma supported cells within the primitive hematopoietic compartment by inhibiting apoptosis of CD45(+)CD34(+) cells committed to the hematopoietic lineage, but have no effect on more mature blood (CD45(+)CD34(-)) cells. Inability of hESC-derived hematopoietic cells cocultured with OP9 stromal cells to engraft in both the adult and newborn NOD/SCID mice after intrafemoral and intrahepatic injection illustrated that although OP9 stromal cells augment hESC-derived hematopoiesis and progenitor output, this optimized environment does not confer or augment repopulating function of specified hematopoietic cells derived from hESCs. OP9 coculture also increases hematopoietic progenitors output from hemogenic precursors overexpressing HOXB4. Our study demonstrates that OP9 cells support both hemogenic precursors and their primitive hematopoietic progeny, thereby providing the first evidence toward understanding the cellular targets and mechanisms underlying the capacity of OP9 stromal cells to support hematopoiesis from ESCs and define the future steps required to achieve the global goal of generating bona fide human hematopoietic stem cells from ESC lines. Disclosure of potential conflicts of interest is found at the end of this article.     

Cobblestone area measuring (CAM) assay: a new way of assessing the potential of human haemopoietic stem cells.

A new in vitro way of scoring the potential (proliferative- differentiative) of human haemopoietic stem cells (HHSC) is presented. We have applied it in the investigation of HHSC behaviour in normal bone marrow specimens under culture conditions. This system describes a modification of some existing culture assays for primitive HHSC function, and proliferation of the cobblestone area forming cell (CAFC) was determined by counting the cobblestone areas (CA) produced every week. The main steps of the assay are: (a) culture of MNC fraction on pre-established fibroblastic confluent layers from the M2.10B4 mouse cell line; (b) weekly counting of CA over a period of 5 weeks; (c) weekly in situ observation of CA morphology; (d) enumeration of secondary progenitors per CA, in the 5th week. The CAM index, expressing the value of the CA kinetic line slope and the number of secondary progenitors per CA were evaluated as factors indicating HHSC proliferative and differentiative potential, respectively. This culture system has the potential to serve as an in vitro assay of human stem cell transplantation. It could be applied to evaluating the potential of HHSC contained in haemopoietic collections of diverse origin, only in combination with measurements of the starting number of CAFC.     

Cord blood CD34+ cells cultured with FLT3L, stem cell factor, interleukin-6, and IL-3 produce CD11c+CD1a-/c- myeloid dendritic cells

Methods that allow expansion of myeloid dendritic cells (MDCs) from CD34(+) cells are potentially important for boosting anti-leukemic responses after cord blood (CB) hematopoietic stem cell transplantation (HSCT). We showed that the combination of early-acting cytokines FLT3-ligand (FL), stem cell factor (SCF), interleukin (IL)-3, and IL-6 supported the generation of CD11c(+)CD16() CD1a()/c() MDCs from CB CD34(+) cells or CB myeloid precursors. Early-acting cytokine-derived MDCs were maintained within the myeloid CD33(+)CD14()CD15() precursors with a mean of 4 x 10(6) cells generated from 1-4 x 10(4) CB CD34(+) cells or myeloid precursors after 2 weeks. After 8-12 days of culture the MDCs expressed higher levels of HLA-DR antigen but lower levels of CD40 and CD86 antigen, compared to adult blood MDCs. At this stage of differentiation, the early-acting cytokine-derived MDCs had acquired the ability to induce greater allogeneic T cell proliferation than monocytes or granulocytes derived from same culture. Early-acting cytokine-derived MDCs exposed to the cytokine cocktail (CC) comprising IL-1beta, IL-6, tumor necrosis factor (TNF)-alpha, and prostaglandin E (PGE)-2, upregulated the surface co-stimulatory molecules CD40 and CD86 and enhanced allogeneic T cell proliferation, as is characteristic of MDCs maturation. The reliable production of MDCs from CB CD34(+) cells provides a novel way to study their lineage commitment pathway(s) and also a potential means of enriching CB with MDCs to improve prospects for DC immunotherapy following CB HSCT.     

Extended in vitro expansion of adult, mobilized CD34+ cells without significant cell senescence using a stromal cell coculture system with single cytokine support

The macrophage colony-stimulating factor-deficient bone marrow stromal cell line OP9, derived from osteopetrotic mice, is known to support hematopoietic stem cell (HSC) expansion as well as hematopoietic differentiation of embryonic stem cells. Coculture of HSC in the OP9 system requires cytokine support to achieve significant cell expansion. Recently, we reported extensive expansion without cell senescence of cord blood (CB)-derived HSC cocultured with OP9 stromal cells for more than 18 weeks with a single cytokine support using human thrombopoietin (TPO). In this study, we evaluated the efficiency of the OP9/TPO coculture system to sustain long-term hematopoiesis of adult, granulocyte colony-stimulating factor mobilized human peripheral blood (PB) CD34(+) cells. Maximum cell expansion was attained during the first 4 weeks of coculture. At the same time, the maximum progenitor cell expansion was demonstrated by the production of colony-forming cells and cobblestone area-forming cells. In contrast to the expansion of CB CD34(+) cells, PB CD34(+) cells showed termination of cultures after 8 weeks, independent of the cell expansion rates attained. The evaluation of cell senescence by assessing the telomere length in most cultures showed no relevant telomere shortening, despite rapid decrease in telomerase activity. Interestingly, increases in telomere length were demonstrated. In conclusion, OP9/TPO system provides extensive stem cell expansion without concomitant telomere erosion for both CB and adult CD34(+) cells. Termination of adult CD34(+) cell cocultures seems to be independent of telomere length.     

Low numbers of megakaryocyte progenitors in grafts of cord blood cells may result in delayed platelet recovery after cord blood cell transplant

Delayed platelet recovery is an inherent problem with cord blood cell transplantation (CBCT). To investigate this problem, the number of human megakaryocyte (MK) progenitor cells in cord blood (CB; n = 24) was measured and compared with that in G-CSF-mobilized peripheral blood stem cells (PBSC; n = 25). The median numbers of colony-forming units for MK (CFU-MK) that were detected by a serum-free assay system in CB and peripheral blood (PB) were 26 (range, 6-102)/10(5) nucleated cells (NC) and 37 (2-540)/10(5) mononuclear cells (MNC), respectively. The numbers of colony-forming units for granulocyte/macrophage (CFU-GM) were 88 (33-241)/10(5) NC in CB and 138 (6.3-1,250)/10(5) MNC in PB. The frequencies of CD34(+) cells in CB and PB were, respectively, 0.44% (0.10-1.07) and 0.98% (0.05-20.8). The numbers of CFU-MK in CB and PBSC were correlated with those of CD34(+) cells. The estimated number of infused CFU-MK in CBCT was 1/15 that of PBSC transplantation (PBSCT), based upon the above data and the widely used standard doses for both types of transplants. Further, the numbers of infused CFU-MK in patients who received allogeneic PBSCT at our institute were inversely correlated with the speed of platelet recovery. These data indicate that delayed platelet recovery after CBCT is simply due to the low number of CFU-MK contained in grafts.     

Characterization of a lineage-negative stem-progenitor cell population optimized for ex vivo expansion and enriched for LTC-IC

Current hematopoietic stem cell transplantation protocols rely heavily upon CD34+ cells to estimate hematopoietic stem and progenitor cell (HSPC) yield. We and others previously reported CD133+ cells to represent a more primitive cell population than their CD34+ counterparts. However, both CD34+ and CD133+ cells still encompass cells at various stages of maturation, possibly impairing long-term marrow engraftment. Recent studies demonstrated that cells lacking CD34 and hematopoietic lineage markers have the potential of reconstituting long-term in vivo hematopoiesis. We report here an optimized, rapid negative-isolation method that depletes umbilical cord blood (UCB) mononucleated cells (MNC) from cells expressing hematopoietic markers (CD45, glycophorin-A, CD38, CD7, CD33, CD56, CD16, CD3, and CD2) and isolates a discrete lineage-negative (Lin-) cell population (0.10% +/- 0.02% MNC, n=12). This primitive Lin- cell population encompassed CD34+/- and CD133+/- HSPC and was also enriched for surface markers involved in HSPC migration, adhesion, and homing to the bone marrow (CD164, CD162, and CXCR4). Moreover, our depletion method resulted in Lin- cells being highly enriched for long-term culture-initiating cells when compared with both CD133+ cells and MNC. Furthermore, over 8 weeks in liquid culture stimulated by a cytokine cocktail optimized for HSPC expansion, TPOFLK (thrombopoietin 10 ng/ml, Flt3 ligand 50 ng/ml, c-Kit ligand 20 ng/ml) Lin- cells underwent slow proliferation but maintained/expanded more primitive HSPC than CD133+ cells. Therefore, our Lin- stem cell offers a promising alternative to current HSPC selection methods. Additionally, this work provides an optimized and well-characterized cell population for expansion of UCB for a wider therapeutic potential, including adult stem cell transplantation.     

Ex vivo expansion of megakaryocyte progenitor cells: cord blood versus mobilized peripheral blood

Thrombocytopenia is a problematic and potentially fatal occurrence after transplantation of cord blood stem cells. This problem may be alleviated by infusion of megakaryocyte progenitor cells. Here, we compared the ability of hematopoietic progenitor cells obtained from cord blood and expanded in culture to that of mobilized peripheral blood cells. The CD34(+) cells were plated for 10 days in presence of thrombopoietin (TPO) alone and combined with stem cell factor (SCF), Flt3-ligand (FL), interleukin-3 (IL-3), IL-6, and IL-11. Cells were analyzed for the CD41 and CD42b expression and for their ploidy status. Ex vivo produced platelets were enumerated. We show that (1) TPO alone was able to induce differentiation of CD34(+) cells into CD41(+) cells, with limited total leucocyte expansion; (2) the addition of SCF to TPO decreased significantly CD41(+) cell percentage in CB, but not in MPB; and (3) in CB, the addition of FL, IL-6, and IL-11 to TPO increased the leukocyte expansion with differentiation and terminal maturation into MK lineage. In these conditions, high numbers of immature CD34(+)CD41(+) MK progenitor cells were produced. Our results thereby demonstrate a different sensitivity of CB and MPB cells to SCF, with limited CB MK differentiation. This different sensitivity to SCF (produced constitutively by BM stromal cells) could explain the longer delay of platelet recovery after CB transplant. Nevertheless, in CB, the combination of TPO with FL, IL-6, and IL-11 allows generation of a suitable number of immature MK progenitor cells expressing both CD34 and CD41 antigens, which are supposed to be responsible for the platelet recovery after transplantation.