人鼠肝组织嵌合体模型的制备

目的研究制备人鼠肝组织嵌合小鼠模型。方法将人骨髓干细胞直接注射到一定日龄胎鼠肝组织,每只注射移植约1×109人骨髓干细胞。用免疫组化对出生一定日龄移植小鼠肝脏进行甲胎蛋白免疫组织化学检测,检定分析人肝细胞在小鼠体内嵌合生长情况。结果移植人骨髓干细胞胎鼠出生2月龄、12月龄可检测到甲胎蛋白。结论将人骨髓干细胞移植小鼠肝脏内能够存活并分化成人肝细胞并能够长期存活。     

In utero bone marrow transplantation of fetal baboons with mismatched adult baboon marrow.

In utero bone marrow transplantation to fetuses offers the potential advantage of ameliorating the effects of genetic disorders by transplanting allogeneic hematopoietic stem cells into recipients who are immunoincompetent and require no preparative regimen. Therefore, we undertook studies to examine the feasibility of in utero bone marrow transplantation of unrelated allogeneic adult bone marrow into fetal baboons. Thirty-one baboon fetuses were transplanted between the ages of 60 and 160 days gestation (normal gestation, 182 days) with unrelated allogeneic adult bone marrow containing a different isozyme of glucose-phosphate isomerase (GPI). Approximately one third of the 80-day fetuses demonstrated engraftment 1 month after transplantation. Three of three of the initial chimeras died in utero 45 to 80 days after transplantation and the remaining chimeras lost their graft. Furthermore, 80-day fetal baboons were able to recognize donor cells, maternal cells, and other adult baboon peripheral blood cells in a mixed lymphocyte culture (MLC) reaction but still could engraft with allogeneic bone marrow. In contrast all nonchimeric animals survived to term. These data suggest that fetal transplantation of primates is feasible using techniques employed in these studies and that transplantation of younger fetuses who are immunocompetent should be attempted.     

Human adipose stromal cells expanded in human serum promote engraftment of human peripheral blood hematopoietic stem cells in NOD/SCID mice

Human mesenchymal stem cells (hMSC), that have been reported to be present in bone marrow, adipose tissues, dermis, muscles, and peripheral blood, have the potential to differentiate along different lineages including those forming bone, cartilage, fat, muscle, and neuron. Therefore, hMSC are attractive candidates for cell and gene therapy. The optimal conditions for hMSC expansion require medium supplemented with fetal bovine serum (FBS). Some forms of cell therapy will involve multiple doses, raising a concern over immunological reactions caused by medium-derived FBS proteins. In this study, we cultured human adipose stromal cells (hADSC) and bone marrow stroma cells (HBMSC) in human serum (HS) during their isolation and expansion, and demonstrated that they maintain their proliferative capacity and ability for multilineage differentiation and promote engraftment of peripheral blood-derived CD34(+) cells mobilized from bone marrow in NOD/SCID mice. Our results indicate that hADSC and hBMSC cultured in HS can be used for clinical trials of cell and gene therapies, including promotion of engraftment after allogeneic HSC transplantation.     

The effect of splenectomy on bone marrow haematopoiesis in mice.

Splenectomy was performed in strain H mice. Erythrocyte macrocytosis and an increase in the reticulocyte, leucocyte and thrombocyte count were found in the peripheral blood of splenectomized animals; only the erythrocyte count fell in the first 3 weeks after splenectomy. Changes in the myelogram during the first weeks after splenectomy were characterized by an increase in the proportion of cells of the erythrocytic and lymphocytic series. The stem cell count in the bone marrow (determined after Till and McCulloch) was slightly elevated on the 8th day after splenectomy, but in subsequent weeks was rather lower than the control group values. Whatever the post-splenectomy interval at which bone marrow was taken from splenectomized mice, there was no significant difference in the transplantation effect of bone marrow cells on white and thrombocyte haematopoiesis. Bone marrow transplantation was found have a stimulant effect only on the reticulocyte count and the sooner bone marrow was collected after splenectomy, the more pronounced the effect. Changes in the myelogram and splenogram of irradiated mice to which the bone marrow cells of splenectomized mice had been transplanted were relatively small.     

胎肝造血干细胞的移植特性

胚胎发育中,肝脏是一个重要的造血器官。近年来胎肝移植的临床应用重新引起了人们的关注。本文应用染色体的 C-带染色法研究了小鼠骨髓和胎肝造血干细胞在照射受体小鼠中的增殖能力与相互间的竞争作用。实验结果表明胎肝造血干细胞在成年骨髓中的植入率比较同样条件下的成年骨髓造血干细胞低,但胎肝造血干细胞比较成年骨髓造血干细胞具有更强的自我更新或增殖能力。在同种胎肝造血干细胞移植中,为了降低同种移植抗力,提高移植的胎肝造血干细胞在受体中的耐受性,移植前对受体作适当的免疫抑制处理是必要的。因此,克服个体发育屏障和移植免疫屏障是提高同种胎肝造血干细胞移植效果中两个重要的研究课题。     

Human haematopoiesis in steady state and following intense perturbations

Haematopoiesis is comprised of multiple stages, originating from pluripotent stem cells through intermediate progenitors to mature differentiated cells. Consequently, during the development of blood cells numerous sites are potentially exposed to the intense perturbations induced by anticancer chemotherapy. However, little is known about human haematopoietic stem cell kinetics in health and following cytotoxic perturbations. Here we reconstruct the complex in vivo dynamics of haematopoietic populations, including the elusive pluripotent stem cells, with a detailed mathematical representation of the marrow biology. The bone marrow kinetic parameters were estimated by using white blood cell counts routinely collected in patients during high dose chemotherapy (HDCT) followed by autologous peripheral blood stem cell transplantation and granulocyte colony stimulating factor (G-CSF) injections. Studying the model performance under a wide variety of parameter values reveals that bone marrow is surprisingly robust in the physiologically feasible parameter space. We infer that the human haematopoietic pluripotent stem cell density is approximately 1 in 2 · 10⁵ mononuclear cells and that most of these cells are quiescent, dividing once in 3–4 weeks. Our results suggest that the re-infused stem cell content is relatively high (10⁴ kg⁻¹ or 1/300 of CD34+ cells) which contributes to both the long-term marrow re-population as well as to short-term support. This study implies that, in most patients, the pluripotent population recovers within 4 months following HDCT. The proposed model accurately predicts the bone marrow dynamics over a wide range of perturbations caused by clinical interventions. It provides valuable insights about the haematopoietic regeneration capacity, predicts the effect of G-CSF manipulation and of ex vivo graft expansion in improving transplantation procedures, and may have implications for effective stem cell gene therapy.     

Human fetal mesenchymal stem cells

Stem cells have been isolated at all stages of development from the early developing embryo to the post-reproductive adult organism. However, the fetal environment is unique as it is the only time in ontogeny that there is migration of stem cells in large numbers into different organ compartments. While fetal neural and haemopoietic stem cells (HSC) have been well characterised, only recently have mesenchymal stem cells from the human fetus been isolated and evaluated. Our group have characterised in human fetal blood, liver and bone marrow a population of non-haemopoietic, non-endothelial cells with an immunophenotype similar to adult bone marrow-derived mesenchymal stem cells (MSC). These cells, human fetal mesenchymal stem cells (hfMSC), are true multipotent stem cells with greater self-renewal and differentiation capacity than their adult counterparts. They circulate in first trimester fetal blood and have been found to traffic into the maternal circulation, engrafting in bone marrow, where they remain microchimeric for decades after pregnancy. Though fetal microchimerism has been implicated in the pathogenesis of autoimmune disease, the biological role of hfMSC microchimerism is unknown. Potential downstream applications of hfMSC include their use as a target cell for non-invasive pre-natal diagnosis from maternal blood, and for fetal cellular and gene therapy. Using hfMSC in fetal therapy offers the theoretical advantages of avoidance of immune rejection, increased engraftment, and treatment before disease pathology sets in. Aside from allogeneic hfMSC in utero transplantation, the use of autologous hfMSC has been brought a step forward with the development of early blood sampling techniques, efficient viral transduction and clonal expansion. Work is ongoing to determine hfMSC fate post-transplantation in murine models of genetic disease. In this review we will examine what is known about hfMSC biology, as well as discussing areas for future research. The implications of hfMSC trafficking in pregnancy will be explored and the potential clinical applications of hfMSC in prenatal diagnosis and fetal therapy discussed.     

Fetal and adult liver stem cells for liver regeneration and tissue engineering

For the development of innovative cell-based liver directed therapies, e.g. liver tissue engineering, the use of stem cells might be very attractive to overcome the limitation of donor liver tissue. Liver specific differentiation of embryonic, fetal or adult stem cells is currently under investigation. Different types of fetal liver (stem) cells during development were identified, and their advantageous growth potential and bipotential differentiation capacity were shown. However, ethical and legal issues have to be addressed before using fetal cells. Use of adult stem cells is clinically established, e.g. transplantation of hematopoietic stem cells. Other bone marrow derived liver stem cells might be mesenchymal stem cells (MSC). However, the transdifferentiation potential is still in question due to the observation of cellular fusion in several in vivo experiments. In vitro experiments revealed a crucial role of the environment (e.g. growth factors and extracellular matrix) for specific differentiation of stem cells. Co-cultured liver cells also seemed to be important for hepatic gene expression of MSC. For successful liver cell transplantation, a novel approach of tissue engineering by orthotopic transplantation of gel-immobilized cells could be promising, providing optimal environment for the injected cells. Moreover, an orthotopic tissue engineering approach using bipotential stem cells could lead to a repopulation of the recipients liver with healthy liver and biliary cells, thus providing both hepatic functions and biliary excretion. Future studies have to investigate, which stem cell and environmental conditions would be most suitable for the use of stem cells for liver regeneration or tissue engineering approaches.     

造血干细胞移植条件对小鼠造血重建的影响

通过同种基因型小鼠构建造血干细胞移植模型,将预处理的全骨髓单个核细胞或c-Kit⁺造血干细胞移植至致死剂量照射的受体小鼠体内,动态监测移植2～16周后受体小鼠体内供体来源细胞造血重建以及嵌合情况,以期揭示不同群体的供体细胞以及预处理等因素对小鼠造血干细胞移植后造血重建的影响。实验结果显示,移植后早期(2周)全骨髓单个核细胞组髓系比例要高于c-Kit⁺细胞移植组,但全骨髓移植组受体小鼠呈现出较大的移植后不良反应,出现脱毛、食欲不振以及体重减轻的症状。c-Kit⁺细胞移植组在淋系重建上要早于全骨髓移植组,供体细胞的嵌合植入也早于全骨髓移植组,但两组实验组最终均能完成造血重建过程。实验结果表明c-Kit⁺细胞移植组在移植后能够较快地实现供体细胞植入,进而开始造血重建,且c-Kit⁺细胞移植组的不良反应要低于全骨髓移植组。结果说明在整体造血重建效果上c-Kit⁺细胞移植组要优于全骨髓移植组。     

Comparative osteogenic transcription profiling of various fetal and adult mesenchymal stem cell sources

Human mesenchymal stem cells (MSC) from adult and fetal tissues are promising candidates for cell therapy but there is a need to identify the optimal source for bone regeneration. We have previously characterized MSC populations in first trimester fetal blood, liver, and bone marrow and we now evaluate their osteogenic differentiation potential in comparison to adult bone marrow MSC. Using quantitative real-time RT-PCR, we demonstrated that 16 osteogenic-specific genes (OC, ON, BSP, OP, Col1, PCE, Met2A, OPG, PHOS1, SORT, ALP, BMP2, CBFA1, OSX, NOG, IGFII) were expressed in both fetal and adult MSC under basal conditions and were up-regulated under osteogenic conditions both in vivo and during an in vitro 21-day time-course. However, under basal conditions, fetal MSC had higher levels of osteogenic gene expression than adult MSC. Upon osteogenic differentiation, fetal MSC produced more calcium in vitro and reached higher levels of osteogenic gene up-regulation in vivo and in vitro. Second, we observed a hierarchy within fetal samples, with fetal bone marrow MSC having greater osteogenic potential than fetal blood MSC, which in turn had greater osteogenic potential than fetal liver MSC. Finally, we found that the level of gene expression under basal conditions was positively correlated with both calcium secretion and gene expression after 21 days in osteogenic conditions. Our findings suggest that stem cell therapy for bone dysplasias such as osteogenesis imperfecta may benefit from preferentially using first trimester fetal blood or bone marrow MSC over fetal liver or adult bone marrow MSC.     

Proliferation activity of stromal stem cells (CFU-f) from hemopoietic organs of pre- and postnatal mice

Stromal stem cells (CFU-f assay) from hemopoietic organs of fetuses, in contrast to adult animals, exhibit a high proliferation activity. This implies that these CFU-f are radiosensitive and potential target cells after radioactive contamination of fetuses. Furthermore, the percentage of CFU-f in DNA synthesis is correlated with the hemopoietic activity in liver, spleen, and bone marrow. As hemopoiesis starts, high numbers of CFU-f are in S phase. In fetal liver, spleen, and bone marrow, values of 70, 43, and 58%, respectively, are reached. As hemopoietic activity decreases in liver and stabilizes in spleen and bone marrow, mitotic activity of these stromal stem cells becomes undetectable.     

SELF-RENEWAL OF COLONY FORMING UNITS (CFU) IN SERIAL BONE MARROW TRANSPLANTATION EXPERIMENTS

The capacity of stem cells (CFU) for self-renewal was tested by transplanting normal bone marrow (primary transplantation) and bone marrow which had been subjected to one or two earlier transplantations (secondary and tertiary transplantation) into lethally irradiated syngeneic recipients. It was found that the capacity for self-renewal is diminished within the first weeks after one or more previous transplantations. This ability of stem cells recovered after a longer interval after the previous transplantation. The time required for this recovery depended upon the number of previous transplantations and amounted to more than 1 or 2 months after one or two transplantations respectively. Shortly after transplantation the CFU/nucleated cell ratio in bone marrow was below normal and its decrease was more pronounced when the bone marrow had been transplanted more often. An increase of the ratio towards normal values was observed in the course of one month after the last transplantation. Measurements of the spleen colony size after transplantation of normal and re-transplanted bone marrow indicated that CFUs from re-transplanted marrow gave slightly smaller spleen colonies than those of normal marrow.
It is concluded that the decreased self-renewal of stem cells shortly after previous transplantations is probably not due to a limitation in the number of normal mitoses they can perform, but to a loss of stem cells by transfer to the compartment of differentiating cells.     

粒细胞集落刺激因子对失代偿期肝硬化患者骨髓干细胞的动员效果及安全性观察

目的观察失代偿期肝硬化患者行自体骨髓干细胞移植前粒细胞集落刺激因子（G-CSF）对骨髓干细胞的动员效果及安全性。方法在51例失代偿期肝硬化患者行自体骨髓干细胞经肝动脉移植术前,连续2 d给予G-CSF 4μg/（kg·d）动员骨髓干细胞。抽取骨髓的当日化验血常规、肝肾功等指标;从患者髂后上棘抽取骨髓150-200 ml,分离收集骨髓单个核细胞并计数,应用流式细胞仪检测CD34＋细胞并计数,观察应用G-CSF期间不良反应的类型和发生率。患者治疗前后比较采用配对t检验进行统计学分析。结果G-CSF皮下注射后,外周血白细胞由术前（3.31±0.96）×10^9/L升至（11.35±1.92）×10^9/L（P〈0.01）,骨髓单个核细胞数（1.91±0.83）×10^9/kg,CD34＋细胞为（2.02±1.29）×10^7/kg;患者皮下注射后,发热率17.6﹪,体温最高38℃,停药后降至正常;腹部胀痛3例,四肢皮肤散发皮疹2例,均未给予特殊处理,2-3 d后恢复正常。结论给予G-CSF皮下注射后提取骨髓干细胞移植治疗失代偿期肝硬化的是一种临床确切有效的、安全的干细胞动员方法。     

In vitro differentiation of reprogrammed murine somatic cells into hepatic precursor cells

Recently, a new approach to reprogram somatic cells into pluripotent stem cells was shown by fusion of somatic cells with embryonic stem (ES) cells, which results in a tetraploid karyotype. Normal hepatocytes are often polyploid, so we decided to investigate the differentiation potential of fusion hybrids into hepatic cells. We chose toxic milk mice (a model of Wilson's disease) and performed initial transplantation experiments using this potential cell therapy approach. Mononuclear bone marrow cells from Rosa26 mice were fused with OG2 (Oct4-GFP transgenic) ES cells. Unfused ES cells were eliminated by selection with G418 for OG2-Rosa26 hybrids and fusion-derived colonies could be subcloned. Using an endodermal differentiation protocol, hepatic precursor cells could be generated. After FACS depletion of contaminating Oct4-GFP-positive cells, the hepatic precursor cells were transplanted into immunosuppressed toxic milk mice by intrasplenic injection. However, five out of eight mice showed teratoma formation within 3-6 weeks after transplantation in the spleen and liver. In conclusion, a hepatic precursor cell type was achieved from mononuclear bone marrow cell-ES cell hybrids and preliminary transplantation experiments confirmed engraftment, but also showed teratoma formation, which needs to be excluded by using more stringent purification strategies.     

A subpopulation of bone marrow cells depleted by a novel antibody, anti-Liv8, is useful for cell therapy to repair damaged liver

We previously reported a new in vivo model named as "GFP/CCl(4) model" for monitoring the transdifferentiation of green fluorescent protein (GFP) positive bone marrow cell (BMC) into albumin-positive hepatocyte under the specific "niche" made by CCl(4) induced persistent liver damage, but the subpopulation which BMCs transdifferentiate into hepatocytes remains unknown. Here we developed a new monoclonal antibody, anti-Liv8, using mouse E 11.5 fetal liver as an antigen. Anti-Liv8 recognized both hematopoietic progenitor cells in fetal liver at E 11.5 and CD45-positive hematopoietic cells in adult bone marrow. We separated Liv8-positive and Liv8-negative cells and then transplanted these cells into a continuous liver damaged model. At 4 weeks after BMC transplantation, more efficient repopulation and transdifferentiation of BMC into hepatocytes were seen with Liv8-negative cells. These findings suggest that the subpopulation of Liv8-negative cells includes useful cells to perform cell therapy on repair damaged liver.     

Transplantation with blood stem cells.

Peripheral blood stem cell transplantation (PBSCT) offers an alternative to autologous bone marrow transplants (A-BMT), especially in malignant diseases with bone marrow contamination. The presence of hemopoietic precursors in peripheral blood has been documented in several animal models and in humans. While many of these precursors might be committed cells with finite renewal capacity, ample evidence suggests that true pluripotent stem cells are circulating in a number sufficient to enable sustained trilineage engraftment after transplantation. Stem cell mobilization is markedly increased in the early recovery phase after intensive chemotherapy and can be promoted by the administration of various cytokines or polyanionic substances. These effects are used to optimize stem cell harvesting by leukapheresis. Clinical trials of PBSCT have been performed in several hundred patients with various hematological and nonhematological malignancies. Recovery was generally more rapid than after A-BMT. However, the envisioned advantage concerning disease control has not been documented so far.     

骨髓干细胞移植治疗肝硬化的基础与临床研究现状

肝硬化是一种临床常见的肝病良性终末期表现。目前临床上尚缺乏有效的治疗措施。肝脏移植是最理想的治疗方法,但受供体肝脏来源限制,且费用昂贵。近年来开展的自体骨髓干细胞(BMSCs)移植治疗,为肝硬化的治疗带来了新的希望。BMSCs主要包括造型血干细胞和间充质干细胞,其具有可塑性,体外通过生长因子,体内利用特定微环境均可诱导BMSCs分化为肝前体细胞和成熟肝细胞,并明显改善肝功能。从动物实验到临床研究亦表明,BMSCs具有来源丰富、费用低廉、损伤小、自体移植不栓塞、无排斥反应等优点,为治疗肝病带来了新思路,有望成为生物人工肝的细胞来源。本文就BMSCs移植治疗肝硬化的研究现状,尤其是移植途径以及在肝脏内定居、迁移和分化机制的示踪观察方法和存在的问题作一综述,以期为从事肝病研究的同仁提供参考依据。通过对BMSCs移植从基础研究及临床应用的最新进展的描述,展示BMSCs在肝硬化治疗方面良好的治疗前景。     

胎肝造血干细胞在扩散盒培养条件下移植特性的变化

经体内扩散盒培养6d 后的 LACA 小鼠胎肝细胞移植给照射的同系成年小鼠,造血干细胞在受体脾脏和骨髓中的有效植入率比正常胎肝细胞明显提高。但这种效果在同种异基因受体小鼠中则完全消失。实验结果表明,个体发育屏障和移植免疫屏障是决定同种胎肝移植能否成功的两个重要因素。胎肝细胞经体内或体外培养后可以模拟造血干细胞在体内的发育成熟,从而增强对成年造血微环境的适应性。用短期体内培养的方法,可以改变胎肝造血干细胞的某些生理特性,从而减弱个体发育屏障,但不能克服胎肝同种移植中的免疫性抗力。为了保证同种胎肝移植的成功,必须进一步同时克服两种屏障。     

Adult stem cells: seing is not being

Recent unexpected observations in adult rodents that stem/progenitor cells located in the bone marrow, but also in other tissues, could, after their transplantation to an irradiated host contribute to the regeneration of damaged organs such as brain, liver, pancreas or muscle, have raised much hope for future therapeutic applications. These data have also initially been interpreted as a proof of a possible transdifferentiation or plasticity of adult stem cells located in these tissues. Additional experiments rigorously analyzed have tempered initial enthusiasm, by showing that if marrow cells do migrate in damaged muscles and liver, their contribution to organ repair is low, and in some cases, explained by cell fusion. Nevertheless, among bone marrow cells, two categories of stem cells now emerge that have a potentially tremendous interest in cell therapy, if we succeed in understanding how to purify, amplify and differentiate these more efficiently and reproducibly.     

The use of CD 34(+) mobilized peripheral blood as a donor cell source does not improve chimerism after in utero hematopoietic stem cell transplantation in non-human primates

In utero hematopoietic stem cell transplantation is a therapeutic procedure that could potentially cure many developmental diseases affecting the immune and hematopoietic systems. In most clinical and experimental settings of fetal hematopoietic transplantation the level of donor cell engraftment has been low, suggesting that even in the fetus there are significant barriers to donor cell engraftment. In postnatal hematopoietic transplantation donor cells obtained from mobilized peripheral blood engraft more rapidly than cells derived from marrow. We tested the hypothesis that use of donor hematopoietic/stem cells obtained from mobilized peripheral blood would improve engraftment and the level of chimerism after in utero transplantation in non-human primates. Despite the potential competitive advantage from the use of CD 34(+) from mobilized peripheral blood, the level of chimerism was not appreciably different from a group of animals receiving marrow-derived CD 34(+) donor cells. Based on these results, it is unlikely that this single change in cell source will influence the clinical outcome of fetal hematopoietic transplantation.