转基因骨髓基质细胞系对人脐血CD34+细胞的体外扩增作用

为探讨转染FL和/或TPO基因骨髓基质细胞系对脐血CD34+细胞的体外扩增效应, 建立了转基因骨髓基质细胞系共培养体系. 采用免疫磁珠法分离人脐血CD34+细胞, 在CD34+细胞不同体外培养体系中取样测试细胞总数、CD34+细胞百分率和CFC(包括CFU-GM 和BFU-E). 结果表明, 在8种不同组合的培养体系中, 转基因基质细胞共培养体系较无基质液体培养体系对细胞总数, CFC, CD34+细胞均具有明显的扩增效应, 其中以SCF + IL-3 + HFT扩增效果最好, 分别扩增了(893.3±52.1), (74.5±5.2)和15.7倍. CFU-GM和BFU-E在第2周时达扩增高峰, 扩增倍数分别为(78.1±5.5)和(57.0±19.7). LTC-IC测定结果显示, 只有SCF + IL-3 + FL + TPO和SCF + IL-3 + HFT组有LTC-IC的存在, 统计学检验无显著性差异. 上述结果提示, 转基因骨髓基质细胞系可通过细胞间的接触协同其他细胞因子增强对脐血CD34+细胞的体外扩增作用.     

FL对脐血造血细胞长期液体培养的影响*

用脐血进行千细胞移植有许多优点,但有一个主要的缺点是可获得的细胞数量有限。因此脐血干细胞的体外扩增对于其临床应用具有重要意义。考察了Flt-3配体(FL)和干细胞因子(SCF)、白介索3(IL一3)、IL-6、粒细胞集落刺激因子(G-csF)、粒细胞巨噬细胞集落刺激因子(GM—CSF)的组合对脐血细胞扩增和分化的影响。培养42d,总细胞最多扩增了385,30±163 51倍(FL+SCF+G．CSF+GM—CSF),粒细胞巨噬细胞集落形成单位(CFU-GM)在第28天达到最高,最高扩增了409．52±189．50倍(FL十SCF+IL-3+IL一6)。FL与SCF等细胞因子具有协同作用,对所有考察的细胞因子组合中,加入FL都使总细胞和CFUGM的扩增倍数增加。FL+SCF培养的总细胞扩增最小,而CFU-GM长时间保持在较高水平,表明这FL和SCF有利于保持造血干细胞的活性,防止细胞分化。在存在G-CSF和GMCSF的培养中,总细胞获得了最大的扩增,但CFU-GM达到最大后很快下降至O,表明G-CSF和GM—CSF促进了细胞的分化。结果提示,细胞因子组合对脐血造血细胞的扩增和分化具有重要的作用．FL和SCF可促进造血细胞的扩增,而G-CSF和GM—CSF等可导致细胞的过度分化。     

Wnt3a 转基因基质细胞的建立及其对脐血CD34+ 造血干/祖细胞扩增作用的研究

Wnt 信号通路在造血干/祖细胞自我更新的过程中发挥至关重要的作用 . 纯化的 Wnt3a 蛋白可以实现造血干/祖细胞的扩增 . 通过病毒转染原代小鼠骨髓基质细胞,建立转基因滋养层细胞 . 通过共培养对转基因滋养层细胞扩增 CD34+ 造血干/祖细胞的作用进行了研究 . 实验结果显示 , 与普通滋养层加细胞因子组相比,经转基因滋养层加细胞因子组培养的 CD34+造血干/祖细胞集落形成能力 (CFC) 是其 (1.55±0.06) 倍;混合集落形成能力是其 (1.95±0.26) 倍;高增殖潜能集落形成能力 (HPP-CFC) 是其 (1.45±0.40) 倍; LTC-IC 活性是其 (3.83±0.86) 倍 . 结果表明,转基因滋养层细胞通过分泌具有天然活性的 Wnt3a 蛋白能在体外有效地扩增造血干/祖细胞的数量 .     

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。     

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。     

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．     

冻存时间对脐血造血细胞体外增殖潜能的影响

目的研究冻存时间对脐血造血细胞增殖潜能的影响.方法在所分离的脐血有核细胞中加入联合低温保护剂Dextran-40+10%DMSO,经梯度降温后置液氮深低温保存.采用无血清造血细胞扩增液对冻存不同时间的脐血造血细胞进行体外扩增,动态监测扩增潜能.结果将冻存1个月、4个月脐血造血细胞体外扩增5周,其总有核细胞分别被扩增了(1499.0±115.6)倍和(1513.0±110.4)倍,FCs均于体外扩增的第3周达到高峰,分别扩增了(53.8±6.3)倍和(54.8±6.7)倍,D34+造血细胞于体外扩增的第2周均达到高峰,分别扩增了(63.8±6.1)倍和(62.4±5.7)倍;统计分析冻存1个月与4个月后造血细胞扩增结果,不存在显著性差异,>0.05.结论在适宜深低温条件下冻存脐血造血细胞,在一定时间内,冻存时间的长短不会导致其增殖潜能下降.     

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。     

骨髓间充质干细胞无血清培养

为建立一种化学成分明确的、能用于体外扩增骨髓间充质干细胞的无血清培养基, 且骨髓间充质干细胞经无血清培养扩增后仍能保持其多向分化的潜能。采用密度梯度离心结合贴壁法从1月龄新西兰大白兔股骨中分离骨髓间充质干细胞, 比较在含10%胎牛血清的培养基(SCM)和自制的化学成分明确的无血清培养基(CDSFM)中骨髓间充质干细胞的形态、增殖能力, 以及扩增后的骨髓间充质干细胞的细胞周期、集落形成能力和成骨、成脂肪分化能力。经过10 d的培养, 骨髓间充质干细胞在自制的无血清培养基中扩增了50倍, 在含10%胎牛血清的培养基中扩增了40倍。在无血清和有血清培养基中扩增后的细胞中G0/G1期比例分别为(80.31%±0.6%)和(75.24%±4.0%), 两者无显著差异(P>0.05)。无血清培养扩增后的骨髓间充质干细胞集落形成率(12.7%±4.0%)低于有血清培养组(28.7%±4.2%), 两者比较差异显著(P<0.01)。经过无血清培养扩增的骨髓间充质干细胞在成骨、成脂肪诱导分化培养基中能够分化成成骨和脂肪细胞。自制的化学成分明确的无血清培养基能够在体外培养扩增骨髓间充质干细胞, 并且维持其干细胞特性, 可以用于细胞治疗以及生物医学研究。     

胚胎干细胞起源的探讨

目前胚胎干细胞(ESCs)建系的取材来源包括桑椹胚的卵裂球、囊胚的内细胞团(ICM)、上胚层细胞和原始生殖细胞(PGCs),甚至从新生鼠睾丸细胞也分离得到类ES样细胞系。这就提出了一个问题,什么是ESCs最接近的体内细胞来源。传统观念常常把ESCs等同于ICM细胞,也有学者认为ESCs更象上胚层细胞,而在已知的分子标记基因方面,ESCs所具有的特征更接近体内早期生殖细胞。不清楚ESCs最接近的体内细胞来源,可能是制约许多品系小鼠和大多哺乳类动物建系成功率提高的原因之一。ESCs系与EG细胞系的分离条件不同表明,加强对ESCs多能性维持基因调控研究具有重要意义。本文从ESCs的经典概念及其发展,早期胚胎细胞和生殖细胞发育规律,早期胚胎细胞、早期生殖细胞和ESCs的关系等方面进行综合分析,认为ESCs可能有多种接近的体内细胞来源。进一步应通过对ESCs建系不同的取材细胞和不同品系的ESCs间进行比较研究,以便弄清ESCs的来源和转化机制,为提高不同物种ESCs建系效率提供理论支持。     

Fine needle aspiration (FNA) cytology of pilomatrixoma

FNA smears from five histologically confirmed cases of pilomatrixoma were reviewed to delineate the cytological features helpful in diagnosis. A combination of basaloid cells, ghost cells and foreign body giant cells appeared to be necessary in FNA smear for a confident cytodiagnosis of pilomatrixoma. Presence of naked nuclei, nucleated squamous cells and calcification were additional features in favour of the diagnosis. Another 10 cases with initial cytodiagnosis of pilomatrixoma or benign skin appendage tumour were reviewed. Using the above criteria, diagnosis of pilomatrixoma was easy in five cases. One case was problematical due to presence of atypical squamous cells. Initially the cytological features were most commonly confused with epidermal inclusion cyst, giant cell lesion or a squamous cell carcinoma. The main reasons for erroneous diagnosis were lack of awareness of cytological features, predominance of one component over the others, and non‐representative FNA smears. Atypia in nucleated squamous cells, and misinterpretation of basaloid cells as malignant can lead to diagnostic dilemma. Adequate clinical data are also necessary.     

A comparison of the tube forming potentials of early and late endothelial progenitor cells

The identification of circulating endothelial progenitor cells (EPCs) has revolutionized approaches to cell-based therapy for injured and ischemic tissues. However, the mechanisms by which EPCs promote the formation of new vessels remain unclear. In this study, we obtained early EPCs from human peripheral blood and late EPCs from umbilical cord blood. Human umbilical vascular endothelial cells (HUVECs) were also used. Cells were evaluated for their tube-forming potential using our novel in vitro assay system. Cells were seeded linearly along a 60 μm wide path generated by photolithographic methods. After cells had established a linear pattern on the substrate, they were transferred onto Matrigel. Late EPCs formed tubular structures similar to those of HUVECs, whereas early EPCs randomly migrated and failed to form tubular structures. Moreover, late EPCs participate in tubule formation with HUVECs. Interestingly, late EPCs in Matrigel migrated toward pre-existing tubular structures constructed by HUVECs, after which they were incorporated into the tubules. In contrast, early EPCs promote sprouting of HUVECs from tubular structures. The phenomena were also observed in the in vivo model. These observations suggest that early EPCs cause the disorganization of pre-existing vessels, whereas late EPCs constitute and orchestrate vascular tube formation.     

树突状细胞与CIK细胞共培养诱生的DCCIK细胞群对肿瘤的杀伤作用

由树突状细胞(DC)与细胞因子诱导的同源杀伤细胞(CIK)的共培养诱生的细胞群(DCCIK)对肿瘤细胞的细胞毒活性的研究。DCCIK细胞体外杀伤肿瘤靶细胞A549(MTT法),效靶比为10∶1、5∶1时杀伤率分别为61%、52%。DCCIK细胞诱导培养3周后,效靶比为10∶1、5∶1时杀伤率分别为64%和56%。数据亦表明DCCIK细胞对靶细胞的杀伤优于CIK细胞。动物体内实验分荷瘤A549、BEL7404和A375三组,每组分(A)DCCIK 化疗、(B)单用化疗。治疗20天、35天后测量各组肿瘤消失率。结果显示:DCCIK 化疗的抑瘤效果明显好于单纯化疗。提示DCCIK细胞有临床应用前景。     

Resistance and augmentation of innate immunity in mice exposed to starvation

Mice were exposed to starvation for 3 days. Body temperature and various parameters were examined. By starvation, body temperature, blood glucose and ACTH decreased, especially on days 2 and 3. The level of corticosterone increased at this time. On the other hand, the number of lymphocytes yielded by the liver, spleen and thymus decreased from day 1 to 3. The change of the distribution of lymphocyte subsets was unique because NK, NKT and extrathymic T cells were stress-resistant in the liver. Conventional T and B cells were stress-sensitive. Reflecting the increased proportion of NK and NKT cells, NK and NKT activities were augmented. The increased proportion of NKT cells produced both IFNγ and IL-4 (Th0-type profile). The proportion and some functions of granulocytes and macrophages increased on Day 1 after starvation. These results suggest that starvation has a potential to increase the functions of unconventional lymphocytes and myeloid cells.     

Ultrastructure of the surface of the iris in the rat eye

Summary The surface structure of the iris in the rat eye was studied by light and electron microscopy.The anterior surface of the rat iris is covered with a discontinuous layer of large, polygonal endothelial cells with microvilli on their surface. Crypts and holes between adjacent endothelial cells extend into the stroma and form there a complicated network of interconnected spaces occupying about one half or more of the volume of the pupillary part of the stroma. The crypts are occasionally partly covered with endothelial cells. The posterior surface is covered with a continuous layer of polyhedronal epithelial cells. These are covered with many folds and processes, partly masked by an amorphous coat. The sphincter pupillae and dilatator muscles are possible to recognize on the scanning electron micrographs as well as blood vessels and nerve fibers in the iris stroma.The endothelial cells show many structural similarities with the endothelial cells on the cornea, probably reflecting their common origin. The results obtained, especially those from the scanning electron microscopic studies, are discussed and interpreted in relation to previous studies. The advantages in using different light and electron microscopic techniques are stressed.Supported by grants from Magnus Bergwall's Stiftelse and the Swedish Medical Research Council (B71-12X-2543-03).     

猪多能干细胞的研究进展

多能干细胞,如胚胎干细胞（embryonic stem cells,ESCs）、诱导多能干细胞（induced pluripotent stem cells,iPSCs）和成体干细胞（adultstemcells,ASCs）,是一类具有巨大潜能的独特细胞。猪作为试验材料,在遗传、代谢、生理生化及基因序列等方面较小鼠更接近于人类,正逐渐成为人类异种移植和再生医学研究的理想生物学模型。然而,目前对猪多能干细胞种类、来源、特征及机制的有限认识直接阻碍了其相关应用。该文将分别对猪ASCs的研究现状、猪类ESCs的分离培养、猪iPSCs的研究进展、多能干细胞间的联系和展望进行论述,以期为从事该领域研究的科研人员提供参考。     

Enhancement of BDNF production by co-cultivation of human neuroblastoma and fibroblast cells

It has been proved that co-cultivation of human neuroblastoma cells and human fibrolast cells can enhance nerve cell growth and the production of BDNF in perfusion cultivation. In batch co-cultivation, maximum cell density was increased up to 1.76×10⁶ viable cells/mL from 9×10⁵ viable cells/mL of only neuroblastoma cell culture. The growth of neuroblastoma cells was greatly improved by culturing both nerve and fibroblast cells in a perfusion process, maintaining 1.5×10⁶ viable cells/mL, which was much higher than that from fed-batch cultivation. The nerve cell growth was greatly enhanced in both fed-batch and perfusion cultivations while the growth of fibroblast cells was not. It strongly implies that the factors secreted from, human fibroblast cells and/or the environments of co-culture system can enhance both cell growth and BDNF secretion. Specific BDNF production rate was not enhanced in co-cultures; however, the production period was increased as the cell growth was lengthened in the co-culture case. Competitive growth between nerve cells and fibroblast cells was not observed in all cases, showing no changes of fibroblast cell growth and only enhancement of the neuroblastoma cell growth and overall BDNF production. It was also found that the perfusion cultivation was the most appropriate process for cultivating two cell lines simultaneously in a bioreactor.