Haemodialysis monocytopenia: differential sequestration kinetics of CD14+CD16+ and CD14++ blood monocyte subsets

In peripheral blood the majority of circulating monocytes present a CD14highCD16- (CD14++) phenotype, while a subpopulation shows a CD14lowCD16+ (CD14+CD16+) surface expression. During haemodialysis (HD) using cellulosic membranes transient leukopenia occurs. In contrast, synthetic biocompatible membranes do not induce this effect. We compared the sequestration kinetics for the CD14+CD16+ and CD14++ monocyte subsets during haemodialysis using biocompatible dialysers. Significant monocytopenia, as measured by the leucocyte count, occurred only during the first 30 min. However, remarkable differences were observed between the different monocyte subsets. CD14++ monocyte numbers dropped to 77 +/- 13% of the predialysis level after 15 min, increasing to > or = 93% after 60 min. In contrast, the CD14+CD16+ subset decreased to 33 +/- 15% at 30 min and remained suppressed for the course of dialysis (67 +/- 11% at 240 min). Approximately 6 h after the end of HD the CD14+CD16+ cells returned to basal levels. Interestingly, the CD14+CD16+ monocytes did not show rebound monocytosis while a slight monocytosis of CD14++ monocytes was occasionally observed during HD. A decline in CD11c surface density paralleled the sequestration of CD14+CD16+ monocytes. Basal surface densities of important adhesion receptors differed significantly between the CD14+CD16+ and CD14++ subsets. In conclusion, during HD the CD14+CD16+ subset revealed different sequestration kinetics, with a more pronounced and longer disappearance from the blood circulation, compared with CD14++ monocytes. This sequestration kinetics may be due to a distinct surface expression of major adhesion receptors which facilitate leucocyte-leucocyte, as well as leucocyte-endothelial, interactions.     

脐血CD34+CD19-造血干/祖细胞体外B细胞分化条件研究

目的:研究体外脐血造血干/祖细胞向B细胞分化的条件.方法:体外免疫磁珠分离纯化脐血CD34+CD19-造血干/祖细胞;在小鼠S-17基质细胞支持下,脐血CD34+CD19-造血干/祖细胞、T3、各种细胞因子共培养建立体外B细胞分化发育培养体系,诱导脐血CD34+CD19-造血干/祖细胞向B细胞分化;用流式细胞仪检测培养的B细胞.结果:T3、IL-7与小鼠S-17基质细胞共培养诱导CD34+CD19-造血干/祖细胞28天时,分化形成的B细胞数可达初始培养细胞的198倍,诱导细胞大部分表达CD10、CD19.结论:在选用的实验条件下,T3、IL-7与小鼠S-17基质细胞体外能诱导脐血造血干/祖细胞的B细胞分化.     

Biological activity of dendritic cells generated from cord blood CD34+ hematopoietic progenitors in IL-7- and IL-13-conditioned cultures

Introduction  Dendritic cells (DCs) are required for initiation of the immune response and may therefore be used for the production of cancer vaccines. As mature DCs (mDCs) are the most potent antigen-presenting cells, there is increasing interest in generating them ex vivo. The present study was designed to obtain mDCs from CD34⁺ hematopoietic progenitors by culturing them in different media. Materials and Methods  Cord blood CD34⁺ hematopoietic progenitors were expanded for 7 days in FST medium ontaining fms-related tyrosine kinase 3 ligand (Flt3-L), stem cell factor (SCF), and thrombopoietin (TPO). Then the cells were divided into three parts and cultured for 21 days in different media: FST medium or FST enriched in interleukin (IL)-3 (FST3 medium) or supplemented with IL-7 and IL-13 (FST713 medium). At the end of culture part of the cells was harvested, counted, and analyzed while the other part was matured with proinflammatory cytokines for 2 days. The cells’ phenotypes, ability to induce proliferation of allogeneic lymphocytes in the mixed lymphocyte reaction (allo-MLR), chemotaxis, phago–cytosis, and O₂ ⁻ production were determined. Results  The average fold increase of DCs at the end of culture in FST medium was 127, in FST3 1043, and in FST713 71. In comparison with the other media, FST713 medium supported the generation of mDCs that were characterized by higher expression of CD83, costimulatory molecules, and HLA-DR, enhanced ability to induce allo-MLR and migration to –macrophage inflammatory protein (MIP) 3β poor phagocytosis, and O₂⁻ production. Conclusions  This study indicates that FST713 medium allows the generation of limited numbers of more mature DCs, while FST3 medium leads to the production of immature DCs in high numbers.     

Implication of delayed TNF-alpha exposure on dendritic cell maturation and expansion from cryopreserved cord blood CD34+ hematopoietic progenitors

Most currently used systems for dendritic cell (DC) production from progenitors entail tumor necrosis factor alpha (TNF-alpha) at the onset of cell culture, based on the notion that TNF-alpha might be required in the early stages of DC development. To optimize conditions for DC expansion from cryopreserved cord blood (CB) CD34+ hematopoietic progenitors, we took a dynamic approach to define the timing of TNF-alpha exposure to the culture. We cultured cord blood CD34+ cells in RPMI-1640 with 10% human AB plasma, stem cell factor (days 1-6), granulocyte-macrophage colony-stimulating factor (days 1-18), interleukin-4 (days 6-18) and varying schedules of TNF-alpha (0-144 h after thawing). Expression of the DC-associated markers, including CD83/CD1a, HLA DR/CD86/CD80, CD14/CD40, was monitored every 3 days. Our data demonstrate that delayed TNF-alpha exposure by 48-72 h after thawing gave rise to two- to three-fold increase in the yield of CD83+ DCs that were highly active in stimulating allogeneic T-cell proliferation compared to immediate TNF-alpha exposure. Thus, the immediate exposure of cryopreserved cord blood CD34+ cells to TNF-alpha, potentially compromising DC expansion, should be avoided. This finding should be of significant consideration when using cryopreserved CD34+ progenitor cells as a source of immunologically competent DCs in a clinical setting.     

CD16+ and CD16- human blood monocyte subsets differentiate in vitro to dendritic cells with different abilities to stimulate CD4+ T cells.

Experimental protocols for cancer immunotherapy include the utilization of autologous monocyte-derived dendritic cells (moDC) pulsed with tumor antigens. However, disease can alter the characteristics of monocyte precursors and some patients have increased numbers (up to 40%) of the minor CD16(+) monocyte subpopulation, which in healthy individuals represent 10% of blood monocytes. At the present, the capacity of CD16(+) monocytes to differentiate into DC has not been evaluated. Here, we investigated the ability of CD16(+) monocytes cultured with granulocyte- macrophage colony-stimulating factor, IL-4 and tumor necrosis factor-alpha to generate DC in vitro, and we compared them to DC derived from regular CD16(-) monocytes. Both monocyte subsets gave rise to cells with DC characteristics. They internalized soluble and particulate antigens similarly, and both were able to stimulate T cell proliferation in autologous and allogeneic cultures. Nevertheless, CD16(+) moDC expressed higher levels of CD86, CD11a and CD11c, and showed lower expression of CD1a and CD32 compared to CD16(-) moDC. Lipopolysaccharide-stimulated CD16(-) moDC expressed increased levels of IL-12 p40 mRNA and secreted greater amounts of IL-12 p70 than CD16(+) moDC, whereas levels of transforming growth factor-beta1 mRNA were higher on CD16(+) moDC. Moreover, CD4(+) T cells stimulated with CD16(+) moDC secreted increased amounts of IL-4 compared to those stimulated by CD16(-) moDC. These data demonstrate that both moDC are not equivalent, suggesting either that they reach different stages of maturation during the culture or that the starting monocytes belong to cell lineages with distinct differentiation capabilities.     

脐血CD34+造血干/祖细胞基因表达图谱的研究

目的：通过脐血CD34^＋造血干／祖细胞的基因表达分析，理解造血干／祖细胞生物学特性。方法：利用MiniMACS免疫磁珠法从脐血细胞中分离CD34^＋造血干／祖细胞，提取总RNA，用SMART-PCR技术从微量RNA中扩增产生足够量的cDNA用于高密度点阵膜分析检测CD34^＋造血干／祖细胞表达的基因。结果：在所检测的588个基因中，发现63个基因具有显著的表达水平，其中18个基因强表达。这些基因主要涉及造血干细胞增殖、分化、应激响应、凋亡、转录调节以及细胞周期等。结论：对理解脐血干／祖细胞生物学性质以及指导造血干细胞体外培养提供了分子生物学基础。     

High efficiency electroporation of human umbilical cord blood CD34+ hematopoietic precursor cells.

Human umbilical cord blood provides an alternative source of hematopoietic cells for purposes of transplantation or ex vivo genetic modification. The objective of this study was to evaluate electroporation as a means to introduce foreign genes into human cord blood CD34+ cells and evaluate gene expression in CD34+/CD38(dim) and committed myeloid progenitors (CD33+, CD11b+). CD34+ cells were cultured in X-VIVO 10 supplemented with thrombopoietin, stem cell factor, and Flt-3 ligand. Electroporation efficiency and cell viability measured by flow cytometry using enhanced green fluorescent protein (EGFP) as a reporter indicated 31% +/- 2% EGFP+ /CD34+ efficiency and 77% +/- 3% viability as determined 48 hours post-electroporation. The addition of allogeneic cord blood plasma increased the efficiency to 44% +/- 5% with no effect on viability. Of the total CD34+ cells 48 hours post-electroporation, 20% were CD38(dim)/EGFP+. CD34+ cells exposed to interleukin-3, GM-CSF and G-CSF for an additional 11 days differentiated into CD33+ and CD11b+ cells, and 9% +/- 3% and 8% +/- 7% were expressing the reporter gene, respectively. We show that electroporation can be used to introduce foreign genes into early hematopoietic stem cells (CD34+/CD38(dim)), and that the introduced gene is functionally expressed following expansion into committed myeloid progenitors (CD33+, CD11b+) in response to corresponding cytokines. Further investigation is needed to determine the transgene expression in functional terminal cells derived from the genetically modified CD34+ cells, such as T cells and dendritic cells.     

Effect of tresperimus on in vitro human cord blood CD34+ cell differentiation

Tresperimus, an analogue of 15-deoxyspergualin (15-DSG), is immunosuppressive and prevents lethal graft-versus-host disease following allogeneic bone marrow transplantation in mice. Here, we present an in vitro dose response study examining the ability of tresperimus to support clonogenesis in cultured CD34+ cord blood stem cells. Our findings revealed that only the lowest dose examined, 0.5 microg tresperimus/ml, supports normal myelopoiesis, erythropoiesis and megakaryopoiesis. Greater concentrations of the drug induced dose-dependent inhibition of clonogenesis. This latter effect was not due to apoptosis and was reversible by drug withdrawal. We conclude that tresperimus at 0.5 microg/ml supports the clonogenic potential of cord blood CD34+ cells. Dose-dependent inhibition of clonogenesis was completely reversible following drug withdrawal. These results may be of clinical interest as tresperimus is currently used in phase I-III studies for the prevention of graft versus host disease in recipients of allogeneic bone marrow.     

早期作用造血因子对人脐血CD34^＋细胞的体外扩增作用

为了观察早期作用造血细胞因子ＳＣＦ、ＦＬ、ＩＬ－３、ＩＬ－６、ＴＰＯ单独及联合应用,对脐血ＣＤ３４＋细胞的体外扩增作用。我们用吸附单克隆抗体一磁珠分离系统富集人脐血ＣＤ３４＋细胞,在体外液体培养体系中加入不同的细胞因子扩增４周,每周取样计数有核细胞总数及集落形成细胞（ＣＦＣ）数。结果表明：用磁性细胞分离议富集脐血ＣＤ３４＋细胞纯度为８０％～８７％;一些细胞因子有明显的协同效应,其联合应用的扩增作用显著高于单因于作用：ＳＣＦ＋ＦＬ存在下,ＩＬ－３是有效扩增有核细胞总数及ＣＦＣ的关键因子了;细胞因子ＳＣＦ＋ＦＬ＋ＩＬ－３和ＳＣＦ＋ＦＬ＋ＩＬ－３＋ＩＬ－６组合对有核细胞总数及ＣＦＣ均有良好的扩增效应,培养２周时对ＣＦＣ的扩增倍数分别为３８．３±４．４和２９．６±２．７倍,可满足成人移植及基因治疗等的需要。     

PGE_2促进人脐血CD34~+造血祖细胞向淋巴样树突状细胞分化

为了探讨前列腺素E2(protaglandin E2,PGE2)对人外周血CD14+单核细胞和脐血CD34+造血祖细胞(hematopoieticprogenitor cells,HPC)体外诱导pDC分化的影响。分别采用IL-4+GM-CSF+TNF-α和SCF+Flt-3L+GM-CSF+TNF-α诱导人外周血CD14+单核细胞和CD34+HPC向pDC分化,采用流式细胞仪分析细胞表型,并观察PGE2加入培养体系后对pDC分化的影响。结果:以CD34+HPC为来源,比CD14+单核细胞能诱导出更多数量且具有功能的pDC。培养体系中加入PGE2显著增强了CD34+HPC向pDC的分化,而对CD14+单核细胞的分化却无明显促进作用。PGE2可有效促进脐血CD34+HPC在多种细胞因子的作用下向pDC的成熟分化。     

Human CD16+ and CD16- monocyte subsets display unique effector properties in inflammatory conditions in vivo

Two major subsets of human Mo are identified based on CD14 and CD16 expression: the classical CD16(-) Mo and the minor CD14(+)CD16(+) Mo. In vitro studies suggested distinct function and differentiation potential for each cell population. However, the in vivo relevance of these findings remains unclear. To evaluate the development and function of human Mo in an in vivo model, we transferred both Mo subpopulations into the peritoneum of immunocompromised mice in homeostatic or inflammatory conditions. Inflammation was induced with soluble LPS or particulate zymosan. CD16(+) were more phagocytic and produced higher amounts of TNF and IL-6 than CD16(-) Mo early after transfer with zymosan. They also produced higher levels of β2-defensin in any condition evaluated, which could represent a new marker for this subpopulation. In contrast, differentiating CD16(-) Mo (24 h after transfer) acquired greater APC capacity in LPS-induced peritonitis, whereas none of the Mo subsets attained this ability with zymosan. CX(3)CL1 supported the survival of both Mo subsets in vivo. Similar Mo subpopulations were present in human peritonitis. These results support the idea of specialized roles of the Mo subset, where CD16(+) might act in an immediate innate immune response, whereas CD16(-) could have a major role as APCs.     

Expansion of LTC-ICs and maintenance of p21 and BCL-2 expression in cord blood CD34(+)/CD38(-) early progenitors cultured over human MSCs as a feeder layer

Allogeneic transplantation with umbilical cord blood (UCB) is limited in adult recipients by a low CD34(+) cell dose. Clinical trials incorporating cytokine-based UCB in vitro expansion have not demonstrated significant shortening of hematologic recovery despite substantial increases in CD34(+) cell dose, suggesting loss of stem cell function. To sustain stem cell function during cytokine-based in vitro expansion, a feeder layer of human mesenchymal stem cells (MSCs) was incorporated in an attempt to mimic the stem cell niche in the marrow microenvironment. UCB expansion on MSCs resulted in a 7.7-fold increase in total LTC-IC output and a 3.8-fold increase of total early CD34(+) progenitors (CD38(-)/HLA-DR(-)). Importantly, early CD34(+)/CD38(-)/HLA-DR(-) progenitors from cultures expanded on MSCs demonstrated higher cytoplasmic expression of the cell-cycle inhibitor, p21(cip1/waf1), and the antiapoptotic protein, BCL-2, compared with UCB expanded in cytokines alone, suggesting improved maintenance of stem cell function in the presence of MSCs. Moreover, the presence of MSCs did not elicit UCB lymphocyte activation. Taken together, these results strongly suggest that the addition of MSCs as a feeder layer provides improved conditions for expansion of early UCB CD34(+)/CD38(-)/HLA-DR(-) hematopoietic progenitors and may serve to inhibit their differentiation and rates of apoptosis during short-term in vitro expansion.     

Heterogeneity of human blood monocytes: the CD14+CD16+ subpopulation

Previously, human blood monocyte subpopulations were defined by approaches that required their isolation, such as differential sedimentation or adherence. Therefore, enumeration of subpopulations and their analysis in disease remained difficult. Here, Löms Ziegler-Heitbrock suggests that expression of CD14 and CD16 can be used to define at least two subsets of monocytes with distinct functional properties.     

Dendritic cell subsets generated from CD34+ hematopoietic progenitors can be transfected with mRNA and induce antigen-specific cytotoxic T cell responses

Human dendritic cells (DCs) generated in culture from either monocytes or CD34+ hematopoietic progenitor cells (CD34-HPCs) have been used in cancer immunotherapy protocols with encouraging results. Yet an optimal strategy for the delivery of antigen(s) to DCs still remains to be established. Recent studies demonstrated the feasibility of mRNA transfection to load monocyte-derived DCs. It is not known, however, whether DCs derived by culturing CD34-HPC with GM-CSF and TNF-alpha for 9 days (CD34-DCs) can be efficiently transduced with mRNA. Here we show that clinical-grade CD34-DCs generated after 8 days of culture can be transfected with mRNA without significant alteration of cell viability. About 90% of cells transfected with GFP-RNA express GFP 24 h post-transfection. Remarkably, transfected CD34-DCs retain high levels of GFP expression for at least 14 days. CD34-DCs transfected with Flu-MP RNA were highly efficient in inducing the proliferation of Flu-MP-specific CD8+ T cells as measured by tetramer staining. Furthermore, the stimulated CD8+ T cells produced IFN-gamma upon antigenic stimulation and were able to kill targets pulsed with Flu-MP peptide. Both DC subsets in CD34-DCs, CD1a+-DC (Langerhans cells) and CD14+-DC (interstitial DC), were equally transfected with GFP-RNA, and yielded Flu-specific cytotoxic T cells upon transfection with Flu-MP RNA. Thus, RNA can be used to deliver antigens to two distinct myeloid DC subsets in CD34-DC cultures.     

Ex vivo large-scale generation of human platelets from cord blood CD34+ cells

In the present investigation, we generated platelets (PLTs) from cord blood (CB) CD34(+) cells using a three-phase culture system. We first cultured 500 CB CD34(+) cells on telomerase gene-transduced human stromal cells (hTERT stroma) in serum-free medium supplemented with stem cell factor (SCF), Flt-3/Flk-2 ligand (FL), and thrombopoietin (TPO) for 14 days. We then transferred the cells to hTERT stroma and cultured for another 14 days with fresh medium containing interleukin-11 (IL-11) in addition to the original cytokine cocktail. Subsequently, we cultured the cells in a liquid culture medium containing SCF, FL, TPO, and IL-11 for another 5 days to recover PLT fractions from the supernatant, which were then gel-filtered to purify the PLTs. The calculated yield of PLTs from 1.0 unit of CB (5 x 10(6) CD34(+) cells) was 1.26 x 10(11) - 1.68 x 10(11) PLTs. These numbers of PLTs are equivalent to 2.5-3.4 units of random donor-derived PLTs or 2/5-6/10 of single-apheresis PLTs. The CB-derived PLTs exhibited features quite similar to those from peripheral blood in morphology, as revealed by electron micrographs, and in function, as revealed by fibrinogen/ADP aggregation, with the appearance of P-selectin and activated glycoprotein IIb-IIIa antigens. Thus, this culture system may be applicable for large-scale generation of PLTs for future clinical use.     

Comparison of CD34+ subsets and clonogenicity in human bone marrow, granulocyte colony-stimulating factor-mobilized peripheral blood, and cord blood

To compare the clonogenicity and distribution of CD34+ subsets in bone marrow (BM), granulocyte colony-stimulating factor (G-CSF) mobilized peripheral blood (PB) and cord blood (CB), we analyzed in vitro colony formation and CD34+ cells co-expressing differentiation molecules (CD38, HLA-DR), myeloid associated molecules (CD13, CD33), a T-cell associated molecule (CD3), and a B-cell associated molecule (CD19) from mononuclear cells (MNCs) in the three compartments. The proportions of CD34+CD38- cells (BM: 4.4+/-2.8%, PB: 5.3+/-2.1%, CB: 5.9+/-3.9%) and CD34+HLA-DR cells (BM: 4.7+/-3.4%, PB: 5.5+/-2.3%, CB: 6.1+/-3.7%) did not differ significantly among the compartments. In contrast, a significantly higher proportion of CD34 cells of PB and CB co-expressed CD13 (75.0+/-11.4%, 77.7+/-17.3%) and CD33 (67.1 +/-5.7%, 56.8+/-10.3%) compared with those of BM (43.0+/-6.3%, 27.6+/-5.1%) and a significantly higher number of granulocyte-macrophage colony-forming units (CFU-GM) and erythroid burst-forming units (BFU-E) were detected in MNCs derived from PB and CB compared with those from BM (p<0.01). The proportion of CD34+CD19+ cells was higher in BM (34.9+/-11.9%) than those in PB (5.6+/-3.0%) and CB (4.7=2.1%) (p<0.05). The proportion of CD34+CD3+ was comparable in all three compartments. In conclusion, our findings show that MNCs of mobilized PB and CB display similar phenotypic profiles of CD34+ subsets and clonogenicity, different from those of BM.     

Effect of tresperimus on ex vivo expansion of CD34+CD38(-)-enriched cord blood cells

Tresperimus, an analogue of 15-deoxyspergualine (15-DSG), has been found, in rodents, to induce a potent state of tolerance after organ and bone marrow allografts. In a previous study, we have reported that tresperimus at the optimal concentration of 0.5 microgram/ml supports the clonogenic potential of human cord blood CD34+ cells. Dose dependent inhibition of clonogenesis was also observed with complete reversibility following drug withdrawal. In this study, we tested the effect of 0.5 microgram tresperimus/ml on ex vivo expansion of primitive human cord blood CD34+CD38- cells. Our findings revealed that the total number of expanded cells was decreased in the presence of tresperimus. However, the multipotential and erythroid colonies were significantly increased in the presence of tresperimus compared with control cultures done without the test drug. Progenitor cell morphology was comparable in both test and control cultures. The telomerase activity was consistently lower in tresperimus-treated hematopoietic progenitors than in control cultures. These results suggest that tresperimus preserves primitive CD34+CD38- cells in a state of high potentiality while limiting the total number of their differentiated progeny. Bearing in mind that the test drug supports the clonogenic potential of CD34+ cells, the overall findings emphasize the importance of assessing the effect of tresperimus on in vivo long-term hematopoiesis which could predict the potential clinical use of tresperimus in the prevention of graft-versus-host disease in recipients of allogeneic bone marrow.