骨髓基质细胞的特征及其在细胞和基因治疗中的应用

骨髓基质细胞是一类独特的间质干细胞,可分化为多种非造血系的组织。骨髓基质细胞具有贴壁生长的特性,因而易于在体外分离和扩增;另外骨髓基质细胞可在体内外表达多种治疗性的外湖目的基因。因此,骨髓基质细胞被认为是一种理想的治疗性细胞的基因治疗中的靶细胞。本文对骨髓基质细胞的研究进展及其在细胞和基因治疗中的应用作一综述。     

骨髓基质细胞的分离、鉴定以及TH基因的转染与表达

目的是探索骨髓基质细胞的分离培养、鉴定及其接受并表达TH基因的能力。实验中通过密度梯度离心法成功地从成年SD大鼠骨髓中分离获得了骨髓基质干细胞 ,并用流式细胞仪对其进行鉴定 ,纯度可达 75 %。进一步采用复制缺陷型腺相关病毒载体介导的基因转染方法 ,将之改造成为携带lacZ与TH基因的工程细胞 ,经X gal染色和TH免疫组化检测 ,转染效率为 (74 .6± 19.4 ) %。实验结果表明骨髓基质细胞易于接受并表达外源基因 ,有望作为运载细胞应用于帕金森病的基因治疗。     

壳聚糖及其改性材料对骨髓基质细胞的作用

壳聚糖是一种广泛应用的生物可降解材料,该论文研究了几种与壳聚糖相关的材料对骨髓基质细胞生长和分化的作用,主要实验方法是在材料表面培养骨髓基质细胞并对其进行诱导促使其向成骨细胞方向分化。通过对细胞生长和分化情况的观察和测定,对几种材料与骨髓基质细胞的亲和性作出了评价。另外,通过ELISA法测定了细胞外基质分子在材料上的吸附量,测量了各材料的表面接触角以研究细胞在材料表面的铺展和增殖。结果表明尽管壳聚糖本身与骨髓基质细胞并不具有很好的亲和性,但通过与明胶混合,壳聚糖的生物相容性得到了明显提高,是很有应用前景的骨修复材料。     

骨髓基质细胞在梗塞区与非缺血区心肌中的分化

目的观察心肌梗塞环境对移植骨髓基质细胞(MSC)向心肌样细胞分化的影响.方法采用成年近交系Wistar大鼠,经左冠状动脉前降支结扎建立急性心肌梗塞模型.术后1周,将来自同种供体、经体外扩增和DAPI标记的MSC分别植入梗塞区和非缺血区心肌.移植后1、2、4周取材、连续冰冻切片,观察两种环境中MSC的分布、迁移及心肌特异性肌钙蛋白T(TnT)的表达.结果植入梗塞区中的MSC扩散较快、增殖似更明显.两种环境中都可见移植细胞表达TnT,且有少数细胞呈现心肌样横纹,但梗塞区移植细胞TnT阳性率显著高于非缺血区.结论急性心肌梗塞环境有利于骨髓基质细胞向心肌样细胞分化.     

人骨髓基质细胞对精原干细胞体外增殖的影响研究

精原干细胞是精子形成的原始细胞,在睾丸组织中的含量极低,而体外有效扩增方法的选择对其移植治疗和抗生育研究十分重要。本实验选用人骨髓基质细胞代替传统饲养层培养人精原干细胞,探讨精原干细胞能否在该饲养层上增殖的可能机制,为人精原干细胞培养提供实验方法和技术指导。骨髓基质饲养层的制备：无菌分离流产5～8月胎儿股骨,     

骨髓基质细胞的辐射效应及其临床意义

小鼠骨髓基质细胞团在γ线照射后的Do值为2.40Gy,但其成灶能力损伤后持续时间较久。正常骨髓基质细胞能促进骨髓GM-CFU-C的生长;照射10-80Gy后的骨髓基质细胞失去这种促进作用。文中讨论了骨髓基质细胞的辐射效应及其临床意义,提出了谨慎选择放射治疗剂量的必要性。     

骨髓基质细胞移植促进心肌梗塞后血管新生机制的研究

目的:通过研究不同时期心肌梗塞区血管生长因子的表达,探讨骨髓基质细胞移植促进心肌梗塞后血管新生的机制.方法:将急性心肌梗塞大鼠随机分为2组.实验组在梗塞后28 d,将同种异体骨髓基质细胞注射到心肌梗塞区.对照组仅注射无血清的培养液.在梗塞后的不同时期取标本动态观察梗塞区VEGF、bFGF的表达和血管新生状况.结果:骨髓基质细胞移植入梗塞区后主要分化为成纤维细胞和血管内皮细胞.实验组心肌梗塞区新生毛细血管数目较对照组明显增加(14±4.7/HPF vs 6±2.4/HPF P＜0.05).对照组梗塞区VEGF和bFGF的表达在梗塞后7 d达高峰,28 d开始下降,第42 d和56 d时表达明显下降.而实验组二者的表达在心肌梗塞后第42 d和56 d明显高于对照组.结论:骨髓基质细胞通过分化为内皮细胞以及促进梗塞区VEGF和bFGF的持续高表达,对血管新生起积极作用.     

罗非鱼鱼皮酶解液对体外培养大鼠骨髓基质细胞的影响

目的:观察两种罗非鱼鱼皮酶解液对大鼠骨髓基质细胞的影响。方法:用密度梯度离心和贴壁筛选的方法获得骨髓基质细胞,用碱性磷酸酶染色法观察是否成功诱导骨髓基质细胞向成骨细胞分化,并分别采用MTT法和PNPP法测定两种酶解液对骨髓基质细胞增殖和碱性磷酸酶活性的影响。结果:密度梯度离心和贴壁筛选可得到较为均一的骨髓基质细胞。这些骨髓基质细胞诱导后可以向成骨细胞分化。两种酶解液作用于骨髓基质细胞时,在浓度0.1mg·ml~(-1)均可以促进骨髓基质细胞增殖,在浓度0.1mg·ml~(-1)1,0.01mg·ml~(-1)均可以提高骨髓基质细胞碱性磷酸酶活力。实验用两种酶解液的三个浓度与成骨诱导液协同作用于骨髓基质细胞时,均没有促进细胞增殖和提高碱性磷酸酶活性的显著作用。结论:两种酶解液可以促进骨髓基质细胞增殖,提高细胞碱性磷酸酶活力;与成骨诱导液协同作用于骨髓基质细胞时,对细胞增殖和碱性磷酸酶活性没有显著促进及提高作用。     

低温冻存对骨髓基质细胞生物学特性的影响

目的：探讨低温冻存对骨髓细胞和贴壁基质细胞生物学特性的影响。方法：取新鲜骨髓和经Dexter法培养14d的骨髓贴壁基质细胞(称“基质细胞”),经-196℃液氮冻存(前者称“冻存骨髓”,后者称“冻存基质细胞”)2周,复温,再用Dexter法培养这些细胞,检测细胞增殖、细胞形态、细胞化学染色、细胞表面抗原及基质细胞支持另一骨髓造血细胞形成的鹅卵石造血区(CAFC),长期培养起始细胞(LTCIC)的变化,比较冻存对骨髓细胞和基质细胞生物学特性的影响。结果：生长特性：冻存骨髓比新鲜骨髓、冻存基质细胞比新鲜基质细胞培养后融合成片的时间延迟,细胞增殖数比也有减低。细胞成分：冻存骨髓比新鲜骨髓形成的成纤维细胞、内皮细胞比率下降,而巨噬细胞和脂肪细胞比率升高,冻存基质细胞上述现象更明显：冻存后含凋亡小体的细胞在骨髓细胞和基质细胞内均有增加。细胞表面抗原：冻存骨髓、冻存基质细胞CD14、HLA-DR抗原表达百分率比新鲜骨髓、新鲜基质细胞高,CD45、CD33反之。支持造血：冻存前后骨髓和基质细胞支持形成的CAFC和LTC-IC,生长良好,无显著差异。结论：骨髓细胞和经培养生成的贴壁基质细胞,经冻存和复温,生物学特性有一定变化,但仍可以保留良好的支持造血重建功能。     

兔BMSCs复合纤维蛋白胶在体外分化为角膜基质细胞的研究

目的：探讨体外诱导兔骨髓间充质干细胞（BMSCs）分化为角膜基质细胞的可行性,并观察纤维蛋白胶（FG）作为细胞支架材料的效果。方法：密度梯度法获得BMSCs,体外诱导实验将细胞分为三组：对照组用普通培养皿、BMSCs培养条件并不加角膜基质细胞共培养的条件下培养;非FG共培养组使用普通培养皿并与角膜基质细胞共培养诱导BMSCs分化;FG共培养组使用铺有FG的培养皿并与角膜基质细胞共培养诱导BMSCs分化。培养1w及2w后用WestenBlot法检测三组细胞Keratocan的表达,在相差显微镜下进行形态学观察。结果：原代培养的BMSCs表现出成体干细胞潜能,CD29染色阳性,符合骨髓基质干细胞的特征。诱导培养2周后对照组BMSCs融合成单层、呈条索状生长;非FG共培养组部分细胞体积变小、多突起,局部呈梭形生长;FG共培养组细胞生长状态良好,部分细胞呈梭形或纺锤形,与FG生物相容性好。Westen检测结果：BMSCs细胞在纤维蛋白胶或普通培养皿上特定培养条件下均能诱导表达角膜基质细胞的特异性蛋白Keratocan。结论：骨髓间充质干细胞在条件培养基下可分化为角膜基质细胞,有望作为治疗角膜疾病及角膜组织工程的备选材料,纤维蛋白胶组织相容性好,可为组织工程提供移植细胞片。     

Enhanced growth of canine bone marrow stromal cell cultures in the presence of acidic fibroblast growth factor and heparin

Summary The ex vivo establishment, expansion, transduction, and reintroduction of autologous bone marrow stromal cells offers a potential efficacious system for somatic cell gene therapy. It is likely that any ex vivo system will require the use of large numbers of cells which express high levels of transgene products. We present a method for routine expansion of canine bone marrow stromal cells, established from initial 10–20 ml marrow aspirates, to greater than 10⁹ cells. This high level expansion of cell cultures uses the stimulatory effect of acidic fibroblast growth factor (aFGF) and heparin. In the absence of these factors, stromal cell cultures grow actively for only 1 to 2 passages, become flattened in morphology, and expand to only 10⁸ cells. In the presence of heparin (5 U/ml), aFGF exerts its effect over a wide range of concentrations (0.1–10 ng/ml) in a dose-dependent manner. The stimulatory effect is dependent on the presence of both aFGF and heparin. Immunocytochemical and cytochemical analyses phenotypically characterize these stromal cells as bone marrow stromal myofibroblasts. Stromal cells grown in the presence of aFGF and heparin grow actively and maintain a fibroblast-like morphology for a number of passages, transduce efficiently with a human growth hormone (hGH) expression vector, and express and secrete high levels of hGH. Human marrow stromal cells were also established and expanded by the same culture method. This culture method should be of great value in somatic cell gene therapy for the delivery of secreted gene products to the plasma of large mammals.     

Ex vivo enrichment of mesenchymal cell progenitors by fibroblast growth factor 2

Bone marrow stromal cells, obtained from postnatal bone marrow, contain progenitors able to differentiate into several mesenchymal lineages. Their use in gene and cell therapy requires their in vitro expansion and calls for the investigation of the culture conditions required to preserve these cells as a stem compartment with high differentiative potential during their life span. Here we report that fibroblast growth factor 2 (FGF-2)-supplemented bone marrow stromal cell primary cultures display an early increase in telomere size followed by a gradual decrease, whereas in control cultures telomere length steadily decreases with increasing population doublings. Together with clonogenic culture conditions, FGF-2 supplementation prolongs the life span of bone marrow stromal cells to more than 70 doublings and maintains their differentiation potential until 50 doublings. These results suggest that FGF-2 in vitro selects for the survival of a particular subset of cells enriched in pluripotent mesenchymal precursors and is useful in obtaining a large number of cells with preserved differentiation potential for mesenchymal tissue repair.     

FLT3配基在人骨髓基质细胞系中的基因转移与表达

目的：研究逆转录病毒介导的FL在骨髓基质细胞系HFCL中的表达。方法：采用脂质体法将重组质粒pLF-SN/HFCL和空载体pLXSN/HFCL转染包装细胞PA317,G418筛选抗性克隆,用抗性克隆上清液感染HFCL。RT－PCR和基因组DNA－PCR检测外源基因mRNA水平的表达及染色体的整合,小鼠CFU－GM集落法检测FL生物学活性。结果：在mRNA水平上有FL的表达,染色体基因组中整合有标记neo基因和FL基因。活性测试结果显示转染的骨髓基质细胞分泌FL。结论：提示骨髓基质细胞可作为基因治疗的靶细胞。     

Differentiation Capacity toward Mesenchymal Cell Lineages of Bone Marrow Stromal Cells Established from Temperature-Sensitive SV40 T-Antigen Gene Transgenic Mouse

Stromal cell lines were established from bone marrow of temperature-sensitive T-antigen gene transgenic mice. These stromal cell lines consisted of fibroblasts, endothelial cells, and preadipocytes. We found that these stromal cell lines exhibited phenotypic changes depending on the inactivation of T-antigen and growth condition; one preadipocyte line was induced toward adipocytes and osteogenic cells, and several preadipocyte and endothelial cell lines were induced toward muscle cells and adipocytes. Some cell lines showed bipotential characters. These results indicated that stromal cells consisting of bone marrow hematopoietic microenvironment are derived from multipotent mesenchymal stem cells.     

Effects of growth factors on multipotent bone marrow mesenchymal stromal cells

Multipotent bone marrow mesenchymal stromal cells are progenitors of various cell types capable of long-term self-renewal. These cells are an adequate model for studying the most important problems in cell biology, such as self-renewal of stem cells and regulation of their differentiation. Moreover, these cells are a promising resource for regenerative medicine. In this context, isolation of the earliest multipotent mesenchymal stromal cells, their in vitro maintenance in an undifferentiated state, and stimulation of their differentiation in a desired direction appear to be most important. To successfully use the multipotent mesenchymal stromal cells both in fundamental studies and in therapy, it is necessary to modify and standardize the composition of culture medium, replacing blood serum with certain growth factors. These factors have influence on the proliferation and differentiation of most cell types, including multipotent mesenchymal stromal cells. This paper is a review of available data concerning the effects of some growth factors on the multipotent mesenchymal stromal cells of the bone marrow.     

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.     

Bone marrow stromal cells selectively stimulate the rapid expansion of lineage-restricted myeloid progenitors

Bone marrow stromal cells serve hematopoietic microenvironments where different blood cells are controlled in their growth and differentiation. To characterize functions of stromal cells, 33 bone marrow stromal cells including preadipocytes, endothelial cells, and fibroblasts were established from transgenic mice harboring temperature-sensitive SV40 T-antigen gene and their selective stimulatory abilities to support large colony formation of lineage-specific hematopoietic progenitor cells (erythroid, monocyte/macrophage, granulocyte, and monocyte-granulocyte) were examined. Among established stromal cells, 27 clones showed erythropoietic stimulatory activity in the presence of erythropoietin. On myeloid progenitors, the stromal cells showed lineage-restricted stimulatory activity and a reciprocal relationship was observed between granulocyte formation and macrophage formation, but these activities were not dependent on the amount of produced colony-stimulating factors (CSFs). Our present study with many stromal cells established from bone marrow indicated that each stromal cell in the bone marrow may provide the preferable microenvironment for a rapid expansion of the lineage-restricted progenitor cells in combination with CSFs. © 1995 Wiley-Liss, Inc.     

Oncostatin M regulates mesenchymal cell differentiation and enhances hematopoietic supportive activity of bone marrow stromal cell lines

Bone marrow stromal cell lines (TBR cell lines) established from temperature-sensitive Simian Virus 40 T-antigen gene transgenic mice exhibited myogenic, osteogenic, and adipogenic differentiation. The effect of oncostatin M (OSM) on such mesenchymal cell differentiation of marrow stromal cell lines was examined. One of those stromal cell lines, TBRB, differentiated into skeletal muscle, and its differentiation was stimulated by OSM, whereas differentiation of TBR10-1 into smooth muscle was inhibited by OSM. TBR31-2 is a bipotent progenitor for adipocytes and osteoblasts, and OSM stimulated osteogenic differentiation while inhibiting adipogenic differentiation. On the other hand, TBR cell lines exhibited various potentials for supporting hematopoiesis in culture. When hematopoietic progenitor cells were cocultured with OSM-stimulated stromal cell lines, TBR10-1 and TBR31-2 exhibited enhanced hematopoietic supportive activity. As responsible molecules for stromal cell dependent hematopoiesis, expression of stem cell factor (SCF) (a ligand of c-Kit), vascular cell adhesion molecule (VCAM-1) (a ligand of VLA-4), and secretion of interleukin (IL)-6 were increased by OSM. OSM affected mesenchymal cell differentiation and promoted the hematopoietic supportive activity of marrow stromal cell lines. As OSM production is induced by cytokines from hematopoietic cells, OSM may be a key factor in mutual regulation between hematopoietic cells and stromal cells in the bone marrow. OSM may play a role as a regulator in maintaining the hematopoietic microenvironment in marrow by coordinating mesenchymal differentiation.