一种新型生物反应器在造血干/祖细胞体外扩增中的应用

针对造血干/祖细胞体外扩增对培养环境的需求, 结合静/动态培养的特点, 开发了一种新型的生物反应器用于造血干/祖细胞的体外扩增。在该生物反应器内, 采用SCF+TPO+Flt-3细胞因子组合, 比较了静态和循环培养两种方式体外扩增脐血CD34+细胞的效果。培养7 d后, 总细胞分别扩增了(13.86 ± 4.26)和(7.23 ± 2.67)倍, 显示静态培养有利于总细胞的扩增; CD34+细胞扩增倍数、培养物中CD34+细胞含量均相近, 无显著性差异; 而CD34+CD38-细胞扩增倍数以及培养物中CD34+CD38?细胞的百分含量分别为(1.82 ± 0.58)和(3.90 ± 0.85)倍以及(9.45 ± 4.85)和(37.47 ± 14.06)%, 循环培养明显高于静态培养。可见, 在该生物反应器内, 采用静态和循环两种培养方式, 均能实现造血干/祖细胞的体外扩增, 但静态培养促使造血干细胞向定向祖细胞分化, 而循环培养则更有利于早期造血干细胞的扩增。     

体外培养脐血单个核细胞与CD34+富集细胞

对比MNC和CD34 +富集细胞在SCF +IL 3+IL 6 +FL +Tpo细胞因子组合下的体外扩增特性 ,发现 :CD34 +富集细胞具有很高的扩增潜力 ,在本实验条件下其总细胞持续扩增了 8周 ,扩增倍数达 312 70 9± 86 40 5倍 ;而MNC在培养至第 4周扩增就已呈现下降趋势 ,最大仅扩增了 5 3 3± 6 2倍。对比集落和CD34 +细胞的扩增发现 ,MNC的集落密度和CD34 +细胞含量由第 0天至第 7天有一个上升的过程 ,而CD34 +富集细胞在培养过程中 ,集落密度和CD34 +细胞含量却始终呈下降趋势。在体外培养过程中 ,CD34 +富集细胞的CFU GM和CD34 +细胞最大分别扩增了 185 7± 14 1和 191 7± 188 8倍 ,明显高于MNC的 12 4± 3 2和 5 0 6± 33 2倍 ;而CD34 +富集细胞和MNC的BFU E则只实现了少量扩增 ,分别为 7 2± 5 2和 10 1± 3 4倍。结果显示 ,从CD34 +富集细胞出发扩增造血干 祖细胞 ,可以得到更多的CD34 +细胞和CFU GM集落形成细胞     

低氧对CD34~ 造血干/祖细胞增殖分化及其对细胞因子依赖性的影响

采用免疫磁珠法分离脐血CD34 造血干 /祖细胞 ,进行低氧和常氧条件下单个核细胞 (MNC)及CD34 细胞的半固体及液体培养 ,计细胞总数和集落产率 ,并通过流式细胞仪检测细胞表型和细胞周期 ,以探讨造血干/祖细胞在低氧环境下增殖分化性能的改变及其对细胞因子反应性的变化。结果显示 :CD34 细胞在低氧条件下生成的BFU E集落数 ( 32 4 8± 41 4/10 4 细胞 )明显增多 (对照为 191 2± 34 5 /10 4 细胞 ,P <0 0 1) ;在无细胞因子存在的液体培养体系中 ,低氧组的BFU E产率 ( 15 2 4± 2 2 6 /10 4 细胞 )明显高于常氧组 ( 74 2± 9 3/10 4 细胞 ,P <0 0 1) ;低氧培养细胞中CD34 细胞的比例高于对照 2 5± 1 2倍 (P <0 0 5 )。但MNC生成的BFU E在常氧和低氧条件下无显著差异。这些结果表明 :体外低氧环境能显著增加CD34 造血干 /祖细胞形成红系祖细胞的产率 ,且使其对细胞因子的依赖性降低 ,并对早期红系祖细胞的维持有增强作用 ,但对粒系祖细胞的增殖则有抑制作用     

体外培养脐血单个核细胞与CD34+富集细胞

对比MNC和CD34⁺富集细胞在SCF+IL-3+IL-6+FL+Tpo细胞因子组合下的体外扩增特性,发现：CD34⁺富集细胞具有很高的扩增潜力,在本实验条件下其总细胞持续扩增了8周,扩增倍数达31270.9±8640.5倍;而MNC在培养至第4周扩增就已呈现下降趋势,最大仅扩增了53.3±6.2倍。对比集落和CD34⁺细胞的扩增发现,MNC的集落密度和CD34⁺细胞含量由第0天至第7天有一个上升的过程,而CD34⁺富集细胞在培养过程中,集落密度和CD34⁺细胞含量却始终呈下降趋势。在体外培养过程中,CD34⁺富集细胞的CFU-GM和CD34⁺细胞最大分别扩增了185.7±14.1和191.7±188.8倍,明显高于MNC的12.4±3.2和50.6±33.2倍;而CD34⁺富集细胞和MNC的BFU-E则只实现了少量扩增,分别为7.2±5.2和10.1±3.4倍。结果显示,从CD34⁺富集细胞出发扩增造血干/祖细胞,可以得到更多的CD34⁺细胞和CFU-GM集落形成细胞。      

低氧环境中微囊化成骨细胞支持造血干/祖细胞扩增

在模拟骨髓造血壁龛(hematopoietic niche)的氧分压条件下,探讨微囊化成骨细胞(osteoblasts,OB)对脐血造血干/祖细胞(HSPC)体外扩增的支持和调控机理．分离培养人髂骨OB,采用聚电解质络合法将第3代的OB以密度为8×105 ml包埋在直径为0.5 mm的明胶-海藻酸钠-壳聚糖(GAC)微胶珠中．将微珠+造血干/祖细胞(A′组)、造血干/祖细胞(B′组)及微珠(C′组)置于6孔板,在5%氧分压下进行培养．同时在20%常氧条件下设置同样分组培养作为对照(A,B,C)．通过流式细胞分析和半固体细胞集落培养,观察比较各培养体系中造血干/祖细胞的扩增,并检测体系内白血病抑制因子(LIF)和白介素-6(IL-6)的含量变化以探讨作用机理．经过倒置相差显微镜观察,人成骨细胞在微珠中分散均匀,生长状态良好．微珠内部有丰富的孔道供营养物质传递,有大量造血干/祖细胞弱黏附于微珠表面．经过7天的培养,A′、B′、A、B四组造血细胞的扩增倍数分别为(49.0 ± 4.6),(3.3 ± 0.5),(17.7 ± 1.2)和(1.9 ± 0.2)．A′、B′、A 组的CD34+细胞分别扩增了(87.6 ± 8.3), (2.2 ± 0.3)和(14.9 ± 1.0)倍,B组则出现下降．A′、B′、A、B四组CFU-Cs集落扩增倍数分别为(9.8 ± 0.8),(3.5 ± 0.4), (6.9 ± 0.7)和(2.6 ± 0.2)．低氧共培养体系比常氧共培养体系和非共培养体系对造血干/祖细胞的扩增有更大的促进作用．A′、B′、C′中IL-6和LIF含量明显高于对应的A、B、C组,与扩增倍数的差异相对应．微囊化成骨细胞对造血干/祖细胞扩增有明显的促进作用,5%氧分压接近体内造血壁龛氧环境,在此环境中成骨细胞分泌细胞因子量增多并通过其对造血干/祖细胞的扩增进行调节．     

一种新型生物反应器在造血干/祖细胞体外扩增中的应用

针对造血干/祖细胞体外扩增对培养环境的需求, 结合静/动态培养的特点, 开发了一种新型的生物反应器用于造血干/祖细胞的体外扩增.在该生物反应器内, 采用SCF TPO Flt-3细胞因子组合, 比较了静态和循环培养两种方式体外扩增脐血CD34 细胞的效果.培养7 d后, 总细胞分别扩增了(13.86 ± 4.26)和(7.23 ± 2.67)倍, 显示静态培养有利于总细胞的扩增; CD34 细胞扩增倍数、培养物中CD34 细胞含量均相近, 无显著性差异; 而CD34 CD38-细胞扩增倍数以及培养物中CD34 CD38-细胞的百分含量分别为(1.82 ± 0.58)和(3.90 ± 0.85)倍以及(9.45 ± 4.85)和(37.47 ± 14.06)%, 循环培养明显高于静态培养.可见, 在该生物反应器内, 采用静态和循环两种培养方式, 均能实现造血干/祖细胞的体外扩增, 但静态培养促使造血干细胞向定向祖细胞分化, 而循环培养则更有利于早期造血干细胞的扩增.     

GST-hDSL重组蛋白的原核表达纯化及对人造血祖细胞的扩增作用

目的:原核表达DSL与谷胱甘肽S转移酶(GST)的融合蛋白并研究观察GST-hDSL对人脐带血CD34 造血祖细胞的体外扩增作用.方法:将人DSL cDNA的蛋白编码序列克隆入原核表达载体pGEX-2T中,在大肠杆菌DH5α中诱导表达融合蛋白,用DEAE阴离子交换柱纯化目的蛋白.然后分离、纯化脐带血CD34 造血祖细胞,不加细胞因子或加入SCF(干细胞生长因子,stem cell factor)和GM-CSF(粒-巨噬细胞集落刺激因子,granuloeyte-macrophage colony-stimulating factor),经过14天的培养,检测GST-hDSL对细胞总数、CD34 细胞百分率、以及集落形成的影响.结果:当SCF和GM-CSF存在时,GST-hDSL组的CD34 细胞百分率,集落(colony forming cells,CFC)数以及高增值潜能集落(high proliferative potential colony forming cells,HPP-CFC)数分别是时照组的1.9、1.2、5.3倍.结论:当与SCF和GM-CSF联合作用时,重组GST-hDSL蛋白对造血祖细胞具有扩增作用.     

用悬浮搅拌培养体系体外大量扩增人脐血造血干/祖细胞

目的 :建立一种简便、有效的脐血造血干 /祖细胞体外大量扩增培养体系。方法 :淋巴细胞分离液分离的脐血单个核细胞在SCF ,IL - 3,IL - 6三种细胞因子的作用下 ,于悬浮搅拌培养体系中培养 ,分析其总细胞数、CFU -GM、CD34+ 细胞的扩增倍数。结果 :脐血单个核细胞在悬浮搅拌培养体系中培养 12天后 ,其总细胞数、CFU -GM、CD34+ 细胞的扩增倍数分别为 6 .31± 1.5 2 ,2 0 .6 3± 1.5 4和 7.11± 1.12。结论 :悬浮搅拌培养体系是脐血造血干 /祖细胞体外大量扩增的有效培养体系。     

逆转录病毒介导的稳定表达E4orf1和绿色荧光蛋白的胎肝窦内皮细胞株的建立

目的:为构建优化的内皮细胞用于造血干细胞(HSCs)的支持培养,通过逆转录病毒载体系统建立稳定表达腺病毒E4区开放读框1(E4orf1)和绿色荧光蛋白(GFP)的人胎肝窦内皮细胞(HFLSECs)株。方法:利用Plat-A细胞将质粒MSCV-N E4orf1和p MX-GFP分别包装为逆转录病毒,共同感染HFLSECs,将原代培养的HFLSECs和转基因的HFLSECs分别在含有0.5、1、2、4μg/m L嘌呤霉素的EGM-2培养基中培养,以测试最适药物筛选浓度,药筛1周后通过流式细胞分选获得稳定转染E4orf1的GFP~+HFLSECs(E4orf1-GFP/HFLSECs)。通过密度梯度离心法从脐带血中分离单个核细胞,利用免疫磁柱分选获得CD34~+造血干/祖细胞(HSPCs),以E4orf1-GFP/HFLSECs作为饲养层联合SCF、TPO、Flt-3L等3种基础造血相关因子进行体外扩增和半固体造血细胞集落培养。结果:0.5μg/m L嘌呤霉素在5 d内即能完全杀死HFLSECs,而转基因的HFLSECs可以正常存活,以此药物浓度加压筛选1周,后续通过流式分选GFP阳性细胞,阳性率为90.5%,在E4orf1-GFP/HFLSECs饲养层支持下,人脐带血来源的CD34~+细胞15 d扩增了360倍,是单纯细胞因子悬浮培养组的2.2倍,且扩增后的HSPCs在体外仍具有多种造血集落形成能力。结论:该细胞株的建立将为构建造血干细胞体外培养体系及研究造血细胞的发育分化提供适宜的微环境。     

脐带间充质干细胞联合UM171对脐血源CD34~+细胞的扩增效果研究

目的研究脐带间充质干细胞联合UM171对脐血来源CD34~+细胞的扩增效果。方法脐血来源CD34~+细胞及脐带来源间充质干细胞分为以下4组进行体外扩增培养10 d:对照组、UM171培养组、间充质干细胞共培养组、UM171联合间充质干细胞共培养组,采用方差分析比较不同组别间细胞扩增倍数及流式表型和集落培养情况。结果脐带间充质干细胞CD105,CD73,CD90,不表达CD14,CD34,CD19,CD45,HLA-DR,经过诱导可以向成骨细胞、脂肪细胞、软骨细胞分化。CD34~+细胞在不同条件下体外培养10 d后,UM171培养组总有核细胞数扩增14倍,CD34~+细胞扩增13.5倍;MSCs共培养组总有核细胞数扩增11倍,CD34~+细胞扩增10倍;联合培养组总有核细胞数扩增达22倍,CD34~+细胞扩增21倍。联合培养组扩增后细胞CD34~+CD38~-比例达(91.49±2.67)﹪,较间充质干细胞培养组(78.11±2.35)﹪及UM171培养组(91.49±2.68)﹪相比差异具有统计学意义(P均0.01)。扩增后细胞集落培养14 d后,各系集落形成良好,UM171扩增组细胞较MSCs扩增组在红系及粒系形成能力方面存在优势。结论脐带血间充质干细胞作为细胞滋养层可提高CD34~+细胞体外扩增效果,UM171在扩增过程中可较好的保持细胞干性,二者联合应用扩增效果最佳,建立的脐带间充质干细胞联合UM171对脐血源CD34~+细胞的扩增方法可用于CD34~+细胞体外扩增培养。     

Expansion of CD34+ cells from human umbilical cord blood by FL and/or TPO gene transfected human marrow stromal cell lines

To elucidate the effect of gene transfected marrow stromal cell on expansion of human cord blood CD34⁺ cells, a culture system was established in which FL and TPO genes were transfected into human stromal cell line HFCL. To establish gene transfected stromal cells co-culture system, cord blood CD34⁺ cells were purified by using a magnetic beads sorting system. The number of all cells and the number of CD34⁺ cells and CFC (CFU-GM and BFU-E) were counted in different culture systems. The results showed that in all 8 culture systems, SCF+IL-3+HFT manifested the most potent combination, with the number of total nucleated cells increasing by (893.3 ±52.1)-fold, total progenitor cells (CFC) by (74.5 ±5.2)-fold and CD34⁺ cells by 15.7-fold. Maximal expansions of CFC and CD34⁺ cells were observed at the end of the second week of culture. Within 14 days of culture, (78.1 ± 5.5)-fold and (57.0 ± 19.7)-fold increases in CFU-GM and BFU-E were obtained. Moreover, generation of LTC-IC from amplified CD34⁺ cells within 28 days was found only in two combinations, i.e. SCF+IL-3+FL+TPO and SCF+IL-3+HFT, and there was no significant difference between these two groups statistically. These results suggest that human umbilical cord blood CD34⁺ cells can be extensively expandedex vivo by using gene transfected stromal cells along with cytokines.     

Human mesenchymal and murine stromal cells support human lympho-myeloid progenitor expansion but not maintenance of multipotent haematopoietic stem and progenitor cells

A major goal in haematopoietic stem cell (HSC) research is to define conditions for the expansion of HSCs or multipotent progenitor cells (MPPs). Since human HSCs/MPPs cannot be isolated, NOD/SCID repopulating cell (SRC) assays emerged as the standard for the quantification of very primitive haematopoietic cell. However, in addition to HSCs/MPPs, lympho-myeloid primed progenitors (LMPPs) were recently found to contain SRC activities, challenging this assay as clear HSC/MPP readout. Because our revised model of human haematopoiesis predicts that HSCs/MPPs can be identified as CD133⁺CD34⁺ cells containing erythroid potentials, we investigated the potential of human mesenchymal and conventional murine stromal cells to support expansion of HSCs/MPPs. Even though all stromal cells supported expansion of CD133⁺CD34⁺ progenitors with long-term myeloid and long-term lymphoid potentials, erythroid potentials were exclusively found within erythro-myeloid CD133^lowCD34⁺ cell fractions. Thus, our data demonstrate that against the prevailing assumption co-cultures on human mesenchymal and murine stromal cells neither promote expansion nor maintenance of HSCs and MPPs.     

Expansion of CD34+ cells from human umbilical cord blood by FL and/or TPO gene transfected human marrow stromal cell lines

To elucidate the effect of gene transfected marrow stromal cell on expansion of human cord blood CD34+ cells, a culture system was established in which FL and TPO genes were transfected into human stromal cell line HFCL. To establish gene transfected stromal cells co-culture system, cord blood CD34+ cells were purified by using a magnetic beads sorting system. The number of all cells and the number of CD34+ cells and CFC (CFU-GM and BFU-E) were counted in different culture systems. The results showed that in all 8 culture systems, SCF+IL-3+HFT manifested the most potent combination, with the number of total nucleated cells increasing by (893.3±52.1)-fold, total progenitor cells (CFC) by (74.5±5.2)-fold and CD34+ cells by 15.7-fold.Maximal expansions of CFC and CD34+ cells were observed at the end of the second week of culture. Within 14 days of culture, (78.1 ± 5.5)-fold and (57.0 ± 19.7)-fold increases in CFU-GM and BFU-E were obtained. Moreover, generation of LTC-IC from amplified CD34+ cells within 28 days was found only in two combinations, I.e. SCF+IL-3+FL+TPO and SCF+IL-3+HFT, and there was no significant difference between these two groups statistically. These results suggest that human umbilical cord blood CD34+ cells can be extensively expanded ex vivo by using gene transfected stromal cells along with cytokines.     

Identification of a clonally expanding haematopoietic compartment in bone marrow

In mammals, postnatal haematopoiesis occurs in the bone marrow (BM) and involves specialized microenvironments controlling haematopoietic stem cell (HSC) behaviour and, in particular, stem cell dormancy and self‐renewal. While these processes have been linked to a number of different stromal cell types and signalling pathways, it is currently unclear whether BM has a homogenous architecture devoid of structural and functional partitions. Here, we show with genetic labelling techniques, high‐resolution imaging and functional experiments in mice that the periphery of the adult BM cavity harbours previously unrecognized compartments with distinct properties. These units, which we have termed hemospheres, were composed of endothelial, haematopoietic and mesenchymal cells, were enriched in CD150+ CD48? putative HSCs, and enabled rapid haematopoietic cell proliferation and clonal expansion. Inducible gene targeting of the receptor tyrosine kinase VEGFR2 in endothelial cells disrupted hemospheres and, concomitantly, reduced the number of CD150+ CD48? cells. Our results identify a previously unrecognized, vessel‐associated BM compartment with a specific localization and properties distinct from the marrow cavity.     

Combination of low O(2) concentration and mesenchymal stromal cells during culture of cord blood CD34(+) cells improves the maintenance and proliferative capacity of hematopoietic stem cells

The physiological approach suggests that an environment associating the mesenchymal stromal cells (MSC) and low O(2) concentration would be most favorable for the maintenance of hematopoietic stem cells (HSCs) in course of ex vivo expansion of hematopoietic grafts. To test this hypothesis, we performed a co-culture of cord blood CD34(+) cells with or without MSC in presence of cytokines for 10 days at 20%, 5%, and 1.5% O(2) and assessed the impact on total cells, CD34(+) cells, committed progenitors (colony-forming cells-CFC) and stem cells activity (pre-CFC and Scid repopulating cells-SRC). Not surprisingly, the expansion of total cells, CD34(+) cells, and CFC was higher in co-culture and at 20% O(2) compared to simple culture and low O(2) concentrations, respectively. However, co-culture at low O(2) concentrations provided CD34(+) cell and CFC amplification similar to classical culture at 20% O(2) . Interestingly, low O(2) concentrations ensured a better pre-CFC and SRC preservation/expansion in co-culture. Indeed, SRC activity in co-culture at 1.5% O(2) was higher than in freshly isolated CD34(+) cells. Interleukin-6 production by MSC at physiologically low O(2) concentrations might be one of the factors mediating this effect. Our data demonstrate that association of co-culture and low O(2) concentration not only induces sufficient expansion of committed progenitors (with respect to the classical culture), but also ensures a better maintenance/expansion of hematopoietic stem cells (HSCs), pointing to the oxygenation as a physiological regulatory factor but also as a cell engineering tool.     

Wnt3a Protein Reduces Growth Factor-Driven Expansion of Human Hematopoietic Stem and Progenitor Cells in Serum-Free Cultures

Ex vivo expansion of hematopoietic stem and progenitor cells (HSPC) is a promising approach to improve insufficient engraftment after umbilical cord blood stem cell transplantation (UCB-SCT). Although culturing HSPC with hematopoietic cytokines results in robust proliferation, it is accompanied with extensive differentiation and loss of self-renewal capacity. Wnt signaling has been implicated in regulating HSPC fate decisions in vivo and in promoting HSPC self-renewal by inhibition of differentiation, but the effects of Wnt on the ex vivo expansion of HSPC are controversial. Here, we demonstrate that exogenous Wnt3a protein suppresses rather than promotes the expansion of UCB-derived CD34⁺ cells in serum free expansion cultures. The reduced expansion was also observed in cultures initiated with Lin^-CD34⁺CD38^lowCD45RA^-CD90⁺ cells which are highly enriched in HSC and was also observed in response to activation of beta-catenin signaling by GSK3 inhibition. The presence of Wnt3a protein during the culture reduced the frequency of multilineage CFU-GEMM and the long-term repopulation ability of the expanded HSPC. These data suggest that Wnt signaling reduces expansion of human HSPC in growth factor-driven expansion cultures by promoting differentiation of HSPC.     

Initial CD34+ cell-enrichment of cord blood determines hematopoietic stem/progenitor cell yield upon ex vivo expansion

Since umbilical cord blood (UCB), contains a limited hematopoietic stem/progenitor cells (HSC) number, successful expansion protocols are needed to overcome the hurdles associated with inadequate numbers of HSC collected for transplantation. UCB cultures were performed using a human stromal‐based serum‐free culture system to evaluate the effect of different initial CD34⁺ cell enrichments (Low: 24 ± 1.8%, Medium: 46 ± 2.6%, and High: 91 ± 1.5%) on the culture dynamics and outcome of HSC expansion. By combining PKH tracking dye with CD34⁺ and CD34⁺CD90⁺ expression, we have identified early activation of CD34 expression on CD34^? cells in Low and Medium conditions, prior to cell division (35 ± 4.7% and 55 ± 4.1% CD34⁺ cells at day 1, respectively), affecting proliferation/cell cycle status and ultimately determining CD34⁺/CD34⁺CD90⁺ cell yield (High: 14 ± 1.0/3.5 ± 1.4‐fold; Medium:22 ± 2.0/3.4 ± 1,0‐fold; Low:31 ± 3.0/4.4 ± 1.5‐fold) after a 7‐day expansion. Considering the potential benefits of using expanded UCB HSC in transplantation, here we quantified in single UCB units, the impact of using one/two immunomagnetic sorting cycles (corresponding to Medium and High initial progenitor content), and the average CD34⁺ cell recovery for each strategy, on overall CD34⁺ cell expansion. The higher cell recovery upon one sorting cycle lead to higher CD34⁺ cell numbers after 7 days of expansion (30 ± 2.0 vs. 13 ± 1.0 × 10⁶ cells). In particular, a high (>90%) initial progenitor content was not mandatory to successfully expand HSC, since cell populations with moderate levels of enrichment readily increased CD34 expression ex‐vivo, generating higher stem/progenitor cell yields. Overall, our findings stress the importance of establishing a balance between the cell proliferative potential and cell recovery upon purification, towards the efficient and cost‐effective expansion of HSC for cellular therapy. J. Cell. Biochem. 112: 1822–1831, 2011. © 2011 Wiley‐Liss, Inc.     

Metallothionein in human immunomagnetically selected CD34+ haematopoietic progenitor cells

Human umbilical CD34⁺ immature haematopoietic cells were rapidly and efficiently obtained from light density MNC (mononuclear cells) by MACS (magnetic cell sorting). An ex vivo expanded population of CD34⁺ was cultured in serum‐free medium supplemented with cytokines FL (flt3 ligand), SCF (stem cell factor) and TPO (thrombopoietin) in order to obtain a sufficient number of CD34⁺ cells. CD34⁺ cells expanded from cord blood for 7 days were demonstrated to increase in the absolute number of CD34⁺ cells by 5.12±2.47‐fold (mean±S.D., n=3). Flow cytometric analysis demonstrated that the percentage of CD34 antigen expression after expansion of the culture was 97.81±1.07%, whereas it was 69.39±10.37% in none‐expanded CD34⁺ cells (mean±S.D., n=3), thus defining a system that allowed extensive amplification accompanied by no maturation. MTs (metallothioneins), low molecular weight, cysteine‐rich metal‐binding proteins, exhibit various functions, including metal detoxification and homoeostasis. We here examined the expression pattern of functional members of the MT gene family in immature CD34⁺ cells and compared it with more mature CD34^? cells in order to strengthen the proposed function of MT in differentiation. Cells were cultured in RPMI 1640 medium, with or without different zinc supplements for 24 h. Relative quantitative expression of MT isogenes in the mature CD34^? cells was higher than in the immature CD34⁺ cells. IHC (immunohistochemical staining) revealed an increased MT protein biosynthesis in CD34^? cells, greater than in CD34⁺ cells. Therefore, the role of MT in differentiation of human haematopoietic progenitor cells from human cord blood is reported for the first time.