HOXB4基因及其在造血干细胞增殖分化调控中的作用

OX家族基因编码一类转录因子 ,参与造血干 /祖细胞的发育调控。其家族成员HOXB4基因具有独特作用。通过提高其表达水平 ,可以在体内外大量扩增造血干细胞。与此同时基本不影响细胞的分化、系特异性及终末细胞的形态和功能。不仅如此 ,HOXB4还可增强胚胎干细胞 (ES细胞 )的造血潜能 ,促进ES细胞向造血细胞分化。因此 ,HOXB4无论是用于基因治疗还是干细胞治疗 ,都将具有广阔的应用前景     

胚胎干细胞向造血细胞分化研究

胚胎干（embryonic stem,ES）细胞是来源于囊胚的内细胞团（inner cell mass,ICM）,具有发育的全能性或多能性,能嵌合到早期胚胎,在体内可以参与各种组织发育甚至包括生殖细胞;在体外分化培养条件下,可以顺序分化出各种组织细胞,与体内完整胚胎发育过程相符合,而且可以通过调节ES细胞某些基因的表达而调节其分化。因此,ES细胞是研究哺乳动物早期胚胎发育、细胞分化及其关键基因鉴定的理想模型。另外,胚胎生殖脊（embryonic germ,EG）细胞系也具有同样的生物学特性,它是由早期胚胎的原始生殖脊（primordial germ,PG）细胞建株而来。最近研究显示：ES细胞在体外不但可以分化为所有造血细胞系,而且还可以分化为具有长期增殖能力的造血干细胞。作者就胚胎干细胞向造血细胞和造血干细胞分化及其诱导因子和调控基因的表达作一综述。     

骨髓内皮细胞来源的可溶性因子调节造血系、内皮系及胚胎干细胞的分化和增殖(英文)

本研究室建立了一支骨髓内皮细胞(bone marrow endothelial cell,BMEC)株。本文综述了这一内皮细胞株细胞的条件培养液(bone marrow endothelial cell-conditioned medium,BMEC-CM)对造血系、内皮系及胚胎干细胞的分化增殖的作用。(1)BMEC-CM促进造血系细胞的分化和增殖;(2)BMEC-CM促进内皮系细胞的分化和增殖;(3)BMEC-CM诱导造血干/祖细胞向内皮系细胞分化;(4)BMEC-CM诱导胚胎干细胞分化为造血细胞和内皮细胞。以上研究成果提示,骨髓内皮细胞分泌可溶性因子支持造血系及内皮系细胞的分化与增殖,促进造血系细胞向内皮系细胞的横向分化,诱导胚胎干细胞分化为造血细胞和内皮细胞。本文进一步阐述了造血系与内皮系之间的密切关系,对缺血性疾病及肿瘤疾病提供有效治疗策略。     

低氧通过上调Wnt5a促进人胚胎干细胞向生血内皮细胞分化

胚胎的早期发育是在低氧条件下进行的,低氧环境在胚胎血管发生及造血发育中起着重要作用,低氧条件能促进胚胎干细胞在体外向内皮细胞和造血细胞的分化,但低氧条件对造血细胞产生的具体作用及相应机制尚不清楚．本研究利用人Es细胞向造血祖细胞定向分化体系,发现低氧环境可以促进CD31＋TIE2＋造血内皮祖细胞的产生,2天后造血内皮祖细胞开始表达终生造血基因．进一步研究发现,低氧能够上调Wnt5a的表达,干涉Wnt5a能够抑制低氧环境对生血内皮细胞分化的促进作用．在正常氧环境下加入Wnt5a产生促进生血内皮细胞分化的效应,该效应与低氧处理促进生血内皮细胞产生的作用相似．本研究首次证明了低氧通过上调Wnt5a的表达促进人Es细胞向生血内皮细胞的分化,为ES细胞向生血内皮细胞的分化及造血祖细胞分化的研究提供了新的线索．     

小鼠胚胎干细胞定向血管内皮和造血细胞分化体系的建立

目的:建立小鼠胚胎干细胞体外定向分化为血管内皮细胞和造血细胞的体系,并验证诱导后2种细胞的表面分子特征。方法:以小鼠胚胎成纤维细胞为饲养层,首先在无血清培养基StemPro中加入骨形态发生蛋白4(BMP4)、激活素A、碱性成纤维细胞生长因子(FGF-Basic)和血管内皮细胞生长因子(VEGF),诱导小鼠胚胎干细胞系R1/E 4 d后形成拟胚体;再将拟胚体消化后与OP9-DL1基质细胞共孵育,分别用干细胞因子(SCF)、VEGF和SCF、FLt3、白细胞介素3(IL-3)诱导向内皮和造血2个方向分化,并以CD31、CD45、CD144、Kit、CD201作为表面标志,流式检测诱导后细胞的表面分子特征和诱导效率;诱导10 d后免疫组化染色,进行内皮细胞的形态学鉴定。结果:诱导分化10 d后,免疫组化染色观察到多个内皮管状结构,流式检测CD31^+的内皮细胞比例为1.35%±0.05%,进一步分析CD31^+CD144^+CD45^-群体,有3.0%±0.2%的细胞表型为Kit^+CD201^+,提示该部分细胞可能是处于分化上游的内皮干祖细胞;CD45^+的造血细胞比例为35.0%±0.5%,其中0.35%±0.05%的细胞表达Kit和CD201,提示该部分细胞可能是处于分化上游的造血干祖细胞。结论:本研究将胚胎干细胞诱导为内皮细胞和造血细胞,并且能诱导出具有内皮、造血干祖细胞分子特征的细胞,可作为理想的体外诱导分化体系。     

胚胎干细胞的生物学特性及体外诱导分化

来源于早期胚胎的胚胎干细胞 (ES)和胎儿生殖脊干细胞 (EG)可在未分化状态下长期增殖培养 ,并保持其多向分化潜能 .体外培养ES细胞的条件已趋于稳定 ,国内外建立了来自人和多种动物早期胚胎的ES细胞系 .某些细胞因子和化学物质等可定向诱导ES细胞分化为各种不同类型的组织细胞 .ES细胞在胚胎发育、细胞分化、转基因动物、移植治疗、药物开发等领域具有广阔的应用前景 .     

造血干/细胞研究进展

造血干/祖细胞是具有高度自我更新能力和多向分化潜能的造血前体细胞.从造血干/祖细胞的生物学特性、检测方法、表面标志及体外扩增、定向诱导分化、造血/祖细胞的细胞治疗及基因治疗等几方面进行了综述.     

建立非基因整合iPSCs体系及提高体外造血分化体系的研究

诱导多能干细胞(induced pluripotent stem cells,i PSCs)在体外可被诱导分化为多种细胞,该项技术在细胞治疗、药物筛选及疾病研究上具有广阔的前景。体外定向诱导其向造血分化可为临床上使用的造血干细胞提供一种新的来源,提高i PSCs的造血分化效率将是i PSCs临床前治疗要解决的关键问题。该研究采用非整合型病毒重编程正常人的外周血来源的单个核细胞(peripheral blood-derived mononuclear cells,PBMCs),诱导生成i PSCs后对其进行体外造血分化实验。结果显示,通过此种方法进行重编程的i PSCs可稳定传代,体内外均可向三胚层分化。使用OP9细胞与i PSCs共培养可分化为造血干/祖细胞,且添加细胞因子可有效提高分化效率。该研究为进一步提高i PSCs造血分化效率提供了重要的实验依据。     

胚胎干细胞的诱导分化研究

胚胎干细胞(embryonic stem cell, ES细胞)是指由胚胎内细胞团(inner cell mass, ICM)细胞经体外抑制培养而筛选得到的细胞, 具有发育上的全能性. 近两年在ES细胞诱导分化方面的研究取得了一些突破性的进展, 其中, ES细胞向生殖细胞分化(2003年)以及首次克隆成功人ES细胞(2004年)先后被评为《科学》杂志当年度十大科学进展之一; 另外, 维持ES细胞不分化状态的关键基因(Nanog)及相关化合物(BIO)的发现, 其自身分化状态调控机理的深入研究, 以及向不同方向诱导分化和应用等的研究成果, 同样受人关注.     

人类多能干细胞向脊髓前角运动神经元定向分化方法研究进展:从发育生物学到临床转化

人类多能干细胞(human pluripotent stem cell,hPSC)包括人胚胎干细胞(embryonic stem cell,ESC)及人诱导多能干细胞(induced pluripotent stem cell,iPSC),它们具有向人体多种类型细胞分化的潜能。近年来,其体外定向分化为脊髓前角运动神经元的研究取得了一定进展。该文基于对神经发育的理解,回顾总结了hPSC向脊髓前角运动神经元定向分化的研究进展,并介绍了它们在研究人类神经发育、对疾病进行体外建模和细胞替代疗法方面的应用。     

胚胎干细胞向血液干细胞定向分化的研究进展

骨髓移植是目前治疗恶性白血病以及遗传性血液病最有效的方法之一。但是HLA相匹配的骨髓捐献者严重短缺,骨髓造血干细胞（hematopoietic stem cells,HSCs）体外培养困难,在体外修复患者骨髓造血干细胞技术不成熟,这些都大大限制了骨髓移植在临床上的应用。多能性胚胎干细胞（embryonic stem cells,ESCs）具有自我更新能力,在合适的培养条件下分化形成各种血系细胞,是造血干细胞的另一来源。在过去的二十多年里,血发生的研究是干细胞生物学中最为活跃的领域之一。小鼠及人的胚胎干细胞方面的研究最近取得了重大进展。这篇综述总结了近年来从胚胎干细胞获得造血干细胞的成就,以及在安全和技术上的障碍。胚胎干细胞诱导生成可移植性血干细胞的研究能够使我们更好地了解正常和异常造血发生的机制,同时也为造血干细胞的临床应用提供理论和实验依据。     

胚胎干细胞诱导分化为雄性生殖细胞的研究进展

胚胎干细胞（embryonic stem cells,ES细胞）具有自我更新及无限分化潜能,理论上可以分化为生殖细胞。目前,在人及鼠中已有体外诱导ES细胞分化为成熟精子的报道。系统阐述影响ES细胞分化为雄性生殖细胞的内源性及外源性因素,并结合国内外最新研究进展总结其诱导分化方法,展望应用前景,期望为从事相关研究的学者提供参考。     

Differentiation of embryonic stem cells in adult bone marrow

Embryonic stem cells (ESCs) are a potential source of generating transplantable hematopoietic stem and progenitor cells, which in turn can serve as "seed" cells for hematopoietic regeneration. In this study, we aimed to gauge the ability of mouse ESCs directly differentiating into hematopoietic cells in adult bone marrow (BM). To this end, we first derived a new mouse ESC line that constitutively expressed the green fluorescent protein (GFP) and then injected the ESCs into syngeneic BM via intra-tibia. The progeny of the transplanted ESCs were then analyzed at different time points after transplantation. Notably, however, most injected ESCs differentiated into non-hematopoietic cells in the BM whereas only a minority of the cells acquired hematopoietic cell surface markers. This study provides a strategy for evaluating the differentiation potential of ESCs in the BM micro-environment, thereby having important implications for the physiological maintenance and potential therapeutic applications of ESCs.     

Canine embryonic stem cells: State of the art

Embryonic stem cells (ESCs) are permanent cell lines that can be maintained in a pluripotent, undifferentiated state. Appropriate environmental stimuli can cause them to differentiate into cell types of all three germ layers both in vitro and in vivo. Embryonic stem cells bear many opportunities for clinical applications in tissue engineering and regenerative medicine. Whereas most of our knowledge on the biology and technology of ESCs is derived from studies with mouse cells, large animal models mimicking important aspects of human anatomy, physiology, and pathology more closely than mouse models are urgently needed for studies evaluating the safety and efficacy of cell therapies. The dog is an excellent model for studying human diseases, and the availability of canine ESCs would open new possibilities for this model in biomedical research. In addition, canine ESCs could be useful for the development of cell-based approaches for the treatment of dogs. Here, we discuss the features of recently reported canine embryo-derived cells and their potential applications in basic and translational biomedical research.     

Avian pluripotent stem cells

Pluripotent embryonic stem cells are undifferentiated cells capable of proliferation and self-renewal and have the capacity to differentiate into all somatic cell types and the germ line. They provide an in vitro model of early embryonic differentiation and are a useful means for targeted manipulation of the genome. Pluripotent stem cells in the chick have been derived from stage X blastoderms and 5.5 day gonadal primordial germ cells (PGCs). Blastoderm-derived embryonic stem cells (ESCs) have the capacity for in vitro differentiation into embryoid bodies and derivatives of the three primary germ layers. When grafted onto the chorioallantoic membrane, the ESCs formed a variety of differentiated cell types and attempted to organize into complex structures. In addition, when injected into the unincubated stage X blastoderm, the ESCs can be found in numerous somatic tissues and the germ line. The potential give rise to somatic and germ line chimeras is highly dependent upon the culture conditions and decreases with passage. Likewise, PGC-derived embryonic germ cells (EGCs) can give rise to simple embryoid bodies and can undergo some differentiation in vitro. Interestingly, chicken EG cells contribute to somatic lineages when injected into the stage X blastoderm, but only germ line chimeras have resulted from EGCs injected into the vasculature of the stage 16 embryo. To date, no lines of transgenic chickens have been generated using ESCs or EGCs. Nevertheless, progress towards the culture of avian pluripotent stem cells has been significant. In the future, the answers to fundamental questions regarding segregation of the avian germ line and the molecular basis of pluripotency should foster the full use of avian pluripotent stem cells.     

Comparative proteomic analysis of mouse embryonic stem cells and neonatal-derived cardiomyocytes

Pluripotent embryonic stem cells (ESCs) spontaneously differentiate via embryo-like aggregates into cardiomyocytes. A thorough understanding of the molecular conditions in ESCs is necessary before other potential applications of these cells such as cell therapy can be materialized. We applied two dimensional electrophoresis to analyze and compare the proteome profiling of spontaneous mouse ESC-derived cardiomyocytes (ESC-DCs), undifferentiated mouse ESCs, and neonatal-derived cardiomyocytes (N-DCs). Ninety-five percent of the proteins detected on the ESC-DCs and N-DCs could be precisely paired with one other, whereas only twenty percent of the ESC proteins could be reliably matched with those on the ESC-DCs and N-DCSs, suggesting a striking similarity between them. Having identified sixty proteins in the said three cell types, we sought to provide possible explanations for their differential expression patterns and discuss their relevance to cell biology. This study provides a new insight into the gene expression pattern of differentiated cardiomyocytes and is further evidence for a close relation between ESC-DCs and N-DCSs.     

Current applications of adipose-derived stem cells and their future perspectives简

Adult stem cells have a great potential to treat various diseases. For these cell-based therapies, adipose-derived stem cells (ADSCs) are one of the most promising stem cell types, including embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs). ESCs and iPSCs have taken center stage due to their pluripotency. However, ESCs and iPSCs have limitations in ethical issues and in identification of characteristics, respectively. Unlike ESCs and iPSCs, ADSCs do not have such limitations and are not only easily obtained but also uniquely expandable. ADSCs can differentiate into adipocytes, osteoblasts, chondrocytes, myocytes and neurons under specific differentiation conditions, and these kinds of differentiation potential of ADSCs could be applied in regenerative medicine e.g., skin reconstruction, bone and cartilage formation, etc. In this review, the current status of ADSC isolation, differentiation and their therapeutic applications are discussed.     

Current applications of adipose-derived stem cells and their future perspectives

Adult stem cells have a great potential to treat various diseases. For these cell-based therapies, adipose-derived stem cells(ADSCs) are one of the most promising stem cell types, including embryonic stem cells(ESCs) and induced pluripotent stem cells(iPSCs). ESCs and iPSCs have taken center stage due to their pluripotency. However, ESCs and iPSCs have limitations in ethical issues and in identification of characteristics, respectively. Unlike ESCs and iPSCs, ADSCs do not have such limitations and are not only easily obtained but also uniquely expandable. ADSCs can differentiate into adipocytes, osteoblasts, chondrocytes, myocytes and neurons under specific differentiation conditions, and these kinds of differentiation potential of ADSCs could be applied in regenerative medicine e.g., skin reconstruction, bone and cartilage formation, etc. In this review, the current status of ADSC isolation, differentiation and their therapeutic applications are discussed.     

Intestinal lineage commitment of embryonic stem cells

Generating lineage-committed intestinal stem cells from embryonic stem cells (ESCs) could provide a tractable experimental system for understanding intestinal differentiation pathways and may ultimately provide cells for regenerating damaged intestinal tissue. We tested a two-step differentiation procedure in which ESCs were first cultured with activin A to favor formation of definitive endoderm, and then treated with fibroblast-conditioned medium with or without Wnt3A. The definitive endoderm expressed a number of genes associated with gut-tube development through mouse embryonic day 8.5 (Sox17, Foxa2, and Gata4 expressed and Id2 silent). The intestinal stem cell marker Lgr5 gene was also activated in the endodermal cells, whereas the Msi1, Ephb2, and Dcamkl1 intestinal stem cell markers were not. Exposure of the endoderm to fibroblast-conditioned medium with Wnt3A resulted in the activation of Id2, the remaining intestinal stem cell markers and the later gut markers Cdx2, Fabp2, and Muc2. Interestingly, genes associated with distal gut-associated mesoderm (Foxf2, Hlx, and Hoxd8) were also simulated by Wnt3A. The two-step differentiation protocol generated gut bodies with crypt-like structures that included regions of Lgr5-expressing proliferating cells and regions of cell differentiation. These gut bodies also had a smooth muscle component and some underwent peristaltic movement. The ability of the definitive endoderm to differentiate into intestinal epithelium was supported by the vivo engraftment of these cells into mouse colonic mucosa. These findings demonstrate that definitive endoderm derived from ESCs can carry out intestinal cell differentiation pathways and may provide cells to restore damaged intestinal tissue.