在大鼠玻璃体内移植猕猴神经前体细胞的方法探索

探索一种简单、可行的异种神经前体细胞眼内移植方法。采用机械性损伤方法造成大鼠视网膜局部受损,然后在损伤眼及对照眼玻璃体内移植绿色荧光蛋白(green fluorescence protein,GFP)标记的猕猴神经前体细胞,观察细胞能否存活。结果显示:经激光共聚焦显微镜检查发现移植细胞在损伤眼及对照眼内均可存活并整合至损伤眼视网膜。实验表明,玻璃体内异种移植GFP标记的猕猴神经前体细胞可以存活并整合,是一种可行的移植方法。     

绿色荧光蛋白标记人脐带间充质干细胞大鼠卵巢移植的实验观察

目的观察人脐带间充质干细胞(MSCs)移植于大鼠卵巢后存活的情况,为MSCs参与动物实验提供实验依据。方法以腺病毒介导绿色荧光蛋白(GFP)基因体外转染MSCs 48 h,于大鼠腹腔卵巢注射移植,于注射移植后1h及移植后3、7、21 d取材并在荧光显微镜下观察MSCs的存活情况。取材石蜡切片行苏木精-伊红(HE)染色观察移植细胞部位组织病理图像。结果 MSCs注射移植后3 d、7 d时GFP荧光表达较强,细胞轮廓清晰,与注射后1h平均吸光度值比较,移植后3、7 d检测荧光吸光度值差异均无统计学意义(P0.05);移植后21 d时GFP荧光表达较弱,吸光度值差异有统计学意义(P0.05)。术后大鼠组织切片光镜下移植的MSCs细胞清晰可见,无急性排斥反应特征出现。结论 MSCs在大鼠腹腔卵巢移植,其与异种个体组织相容性较好。     

小鼠脂联素与绿色荧光蛋白融合基因表达载体的构建及在COS-7细胞中的表达

以绿色荧光蛋白(GFP)基因(gfp)为报告基因,构建小鼠脂联素(mADPN)基因(mAd)与gfp的融合基因mAd/gfp表达载体pCI-neo-apoEHCR-hAATp-mAd-gfp,脂质体法转染体外培养的COS-7细胞,荧光显微镜观察GFP在细胞中的表达可间接反映mADPN的表达,并通过RT-PCR在核酸水平进一步确证mAd的表达.荧光显微镜观察及RT-PCR结果均证明mADPN在COS-7细胞中获得了高效表达,表明mADPN重组表达载体pCI-neo-apoEHCR-hAATp-mAd可以在真核细胞COS-7中高效表达mADPN,为进一步探讨mAd在小鼠体内的表达提供了可行性依据.     

一株水稻促生长内生真菌的绿色荧光蛋白基因标记与示踪

将绿色荧光蛋白基因(gfp)转入到碱蓬内生真菌JP4-1中并检测菌株在水稻幼苗中的定殖情况。采用PEG-Ca Cl2介导的原生质体转化方法将携带gfp基因的p CT74质粒与菌株基因组整合获得转化子,用转化子侵染水稻幼苗,荧光显微镜下示踪JP4-1菌株及其侵染特性。转化子经连续传代6次仍能发出绿色荧光且荧光强度良好,能够稳定遗传;经PCR验证gfp基因已成功转入JP4-1菌株和水稻幼苗植株内并表达。转化可获得稳定表达GFP的JP4-1转化子,JP4-1菌株可定殖于水稻幼苗的根、茎、叶,定殖位置为细胞间隙,其促生作用与野生型菌株无明显差别。     

G-CSF动员外周血单个核细胞移植治疗大鼠缺血缺氧性脑病

目的:应用人外周血单个核细胞移植治疗新生大鼠缺血缺氧性脑病,探讨干细胞移植治疗神经系统损伤性疾病的有效性和安全性。方法:7 d龄SD大鼠随机分为3组(n=12),即正常组、手术组、细胞移植组;在征得同意的情况下利用粒细胞集落刺激因子(G-CSF)对捐献者的外周血进行动员,采用血细胞分离仪分离外周血单个核细胞,并进行鉴定及荧光标记;通过尾静脉注射的方法将标记细胞植入经免疫抑制剂处理的大鼠体内,利用HE染色法观察模型建立后大鼠大脑的损伤情况,利用荧光显微镜观察移植细胞在宿主体内的存活、迁移及分化情况,利用斜板实验明确细胞移植对宿主神经功能损伤情况的影响。结果:移植细胞可在宿主脑内存活,向损伤部位迁移,细胞移植可显著改善缺血缺氧引发的大脑功能损伤;细胞移植后,动物未现不良反应。结论:外周血单个核细胞移植治疗中枢系统损伤性疾病具有较高的安全性与有效性,有望成为一种临床治疗方案。     

一种新的可用于干细胞移植的新西兰白兔青光眼视神经损伤模型

青光眼是一种致盲且不可逆神经退行性疾病,目前还没有能够彻底解决其视野缺失的治疗方法。神经干细胞研究的兴起为该病的治疗带来了可能,且迫切需要一种适用于干细胞移植研究的青光眼造模方法。该实验对新西兰白兔球结膜下注射地塞米松给药,2.5mg/次,一周3次,持续8周。眼底照相显示造模眼眼球屈光间质保持清晰,视乳头凹陷明显扩大、血管呈屈膝状;病理切片显示造模眼视神经明显损伤;海德堡视网膜断层扫描仪(Heidelberg retina tomography,HRT)定量分析显示造模眼盘沿面积减小(1.10±0.88)mm2、杯/盘比增大0.17±0.13,视网膜神经纤维层平均厚度降低(0.44±0.31)mm等青光眼性质病理改变,且均达到极显著水平(P<0.001)。建模成功后,于角膜缘后4mm向造模眼玻璃体注入猕猴神经干细胞,植入5个月后摘取眼球切片,通过荧光显微镜观察到存活的移植细胞。该实验建立了一种简单可靠、重复性强且适用于神经干细胞移植研究的慢性青光眼造模方法。     

鸡胚原肠胚期原条细胞命运决定于其所处的局部微环境

在果蝇、斑马鱼、鸡等三胚层动物胚胎早期发育的原肠胚期,原条两侧的上胚层细胞进入原条经历上皮-间充质转化(EMT),迁移进入囊胚腔,形成松散的中胚层细胞,位于原条不同部位的细胞其迁移路线和分化命运不同,如前部原条细胞贡献于体节和心脏等,而后部原条细胞则迁移至胚外形成血岛。为了研究细胞的迁移途径及分化命运是否会随着细胞所处不同部位微环境的改变而改变,利用传统的移植技术,将宿主鸡胚原条前部的一部分细胞用GFP阳性的相同时期鸡胚原条组织替换,培养一段时间后,用荧光体视显微镜追踪GFP阳性细胞的迁移途径。结果发现,从供体原条后部移植到宿主原条前部的细胞遵循原条前部细胞迁移的路线,反之亦然;原位杂交结果显示移植后的GFP阳性细胞分化为所处部位的细胞类型。上述结果表明:鸡胚原肠胚期原条细胞迁移和分化的命运决定于细胞所处的微环境或者说局部基因表达的时空性。     

绿色荧光蛋白在草鱼肾细胞中的表达

应用阳离子脂质体介导法,将含绿色荧光蛋白（GFP）基因的质粒pEGFP-N1转染到培养成单层的草鱼肾细胞（CIK）中,通过荧光倒置显微镜和特异性RT-PCR方法检测GFP的表达.在荧光倒置显微镜下可见CIK细胞的胞质和胞核均呈现绿色荧光,且细胞核的绿色荧光强度强于细胞质.转染细胞中的转录产物经RT-PCR扩增后,凝胶电泳鉴定出与GFP基因片段分子量大小一致的条带,经测序证明其为GFP基因序列.结果表明,GFP基因可以在草鱼CIK细胞内高效率成功表达,为构建以GFP为报告基因的真核重组质粒及研究草鱼出血病DNA疫苗奠定了重要的基础.     

兔眼增殖性玻璃体视网膜病变模型的建立

目的探讨兔眼增殖性玻璃体视网膜病变模型的建立方法。方法①体外培养兔眼视网膜色素上皮细胞;②兔眼3组,每组6只,分别在玻璃体内注射0.1 mL的生理盐水、1×106细胞及2×106细胞,在不同时间段进行裂隙灯显微镜、间接检眼镜、眼底照像和B超检查,观察成模情况。结果注射后28 d,生理盐水组成模0眼;1×106细胞组成模5眼,其中Ⅰ级眼1只,Ⅱ级眼3只,Ⅲ级眼1只;2×106细胞组成模6眼,其中Ⅱ级眼2只,Ⅲ级眼4只。结论兔眼玻璃体内注射2×106同种视网膜色素上皮细胞建立增殖性玻璃体视网膜病变模型,符合病变发展规律,而且稳定可靠,成模较快,简单易行。     

多能干细胞分化来源视网膜色素上皮细胞移植治疗视网膜变性研究进展

视网膜色素上皮（RPE）对视觉功能的维持起着至关重要的作用。视网膜变性是全球不可治愈性致盲疾病的重要原因,它由视网膜色素上皮功能失常所引起。因此,视网膜色素上皮移植是视网膜变性患者恢复视力的一种最有前景的手段之一。随着干细胞技术的快速发展,从多能干细胞（PSC）到有功能的视网膜色素上皮细胞的体外分化诱导技术已经成熟,其中包括胚胎干细胞（ESCs）和诱导多能干细胞（iPSCs）等。此外,从患者特异性iPSCs分化而来的RPE更能用于阐明发病机理并有针对性地个体治疗。更值得一提的是,经诱导得到RPE的移植不论在动物模型中,还是在临床试验里都已经得到了可喜的治疗效果。本文回顾PSC来源RPE干预治疗视网膜变性的最新研究进展。     

Isolation of progenitor cells from GFP-transgenic pigs and transplantation to the retina of allorecipients

Work in rodents has demonstrated that progenitor transplantation can achieve limited photoreceptor replacement in the mammalian retina; however, replication of these findings on a clinically relevant scale requires a large animal model. To evaluate the ability of porcine retinal progenitor cells to survival as allografts and integrate into the host retinal architecture, we isolated donor cells from fetal green fluorescent protein (GFP)-transgenic pigs. Cultures were propagated from the brain, retina, and corneo-scleral limbus. GFP expression rapidly increased with time in culture, although lower in conjunction with photoreceptor markers and glial fibrillary acid protein (GFAP), thus suggesting downregulation of GFP during differentiation. Following transplantation, GFP expression allowed histological visualization of integrated cells and extension of fine processes to adjacent plexiform layers. GFP expression in subretinal grafts was high in cells expressing vimentin and lower in cells expressing photoreceptor markers, again consistent with possible downregulation during differentiation. Cells survived transplantation to the injured retina of allorecipients at all time points examined (up to 10 weeks) in the absence of exogenous immune suppression without indications of rejection. These findings demonstrate the feasibility of allogeneic progenitor transplantation in a large mammal and the utility of the pig in ocular regeneration studies.     

Nestin‐expressing interfollicular blood vessel network contributes to skin transplant survival and wound healing

Using nestin‐driven green fluorescent protein (ND‐GFP) transgenic mice, we previously demonstrated an inter‐hair‐follicle blood vessel network that expresses ND‐GFP and appears to originate from ND‐GFP expressing hair‐follicle stem cells. We report here that angiogenesis of transplanted skin or healing wounds originates from this ND‐GFP‐expressing microvasculature network. ND‐GFP‐expressing blood vessels were visualized growing from the ND‐GFP‐expressing hair‐follicle stem cell area and re‐establishing the dermal microvasculature network after skin transplantation or wound healing. When the ND‐GFP stem cell area from the vibrissa (whisker) from ND‐GFP mice was transplanted to transgenic mice ubiquitously expressing RFP, we observed chimeric ND‐GFP‐RFP blood vessels, suggesting the joining of inter‐follicular blood vessel networks from the transplant and host. These observations suggest that the inter‐hair‐follicle blood‐vessel network contributes to skin transplant survival and wound healing. J. Cell. Biochem. 110: 80–86, 2010. © 2010 Wiley‐Liss, Inc.     

Survival and differentiation of cultured retinal progenitors transplanted in the subretinal space of the rat

We have shown that embryonic retina contains progenitors which display stem cell properties in vitro. These cells are proliferative and in addition to expressing the neuroectodermal marker, nestin, are multipotential. These properties and the fact that the putative stem cells can differentiate as photoreceptors when exposed to conducive environment identify them as a viable transplantation reagents to address degenerative retinal diseases. Here we report the survival and differentiation of cultured retinal progenitors upon subretinal transplantation. The retinal progenitor grafts, either as neural spheres or in the form of dissociated cells, survived without disrupting the morphology and laminar organization of the host retina. They did not form rosettes, the morphological barrier to the reconstruction of the normal anatomy of the retina. In addition, transplanted progenitors expressed photoreceptor-specific markers, suggesting that progenitors have the potential to differentiate as photoreceptors. Our observations suggest that cultured retinal progenitors can be a viable reagents for therapeutic transplantation.     

胚胎干细胞衍生的视网膜色素上皮细胞移植治疗眼病

Schwartz等报告的用从人胚胎干细胞分化成的视网膜色素上皮细胞（RPE）移植治疗视网膜病,已观察4月,尚属成功。这是首次用从人胚胎干细胞（hESC）定向分化而成的细胞移植至患者取得成功。本文复习RPE移植的历史与现况;hESC分化而成的RPE（hESC-RPE）的实验研究以及临床移植的意义、方法、效果及存在问题,并展望了应用干细胞分化的RPE移植的前景。     

Ultimate Fate of Rod Outer Segments in the Retinal Pigment Epithelium

To investigate the degradation pathway of rod outer segments (ROS) in vivo, we injected gold-labeled ROS into the subretinal space of rabbits using a pars plana approach. Histology and electron microscopy performed on the specimens 72 hr after ROS injection revealed that the retina over the injection site was reattached, the retinal pigment epithelial (RPE) cells were intact, and gold granules were localized inside melanin granules and melanosomes. These results indicate that, in RPE, in vivo degradation of ROS is associated with melanosomes.     

Development and gene expression of nuclear transplants generated by transplantation of cultured cell nuclei into non-enucleated eggs in the medaka Oryzias latipes

To develop nuclear transplantation techniques for the medaka Oryzias latipes, nuclei of cultured cells from transgenic fish were transplanted into unfertilized eggs of the orange-red variety of O. latipes, without enucleation, in two experimental series. In the first experimental series, fibroblast cells cultured from the adult caudal fin were used as donors, which carried the green fluorescent protein (GFP) gene driven by the promoter of the medaka elongation factor 1alpha-A gene. Wild-type body color was another donor genetic marker used in this experimental series. In the second experimental series, cells cultured from 6-day-old embryos were used as donors, which carried the GFP genetic marker driven by the promoter of the medaka beta-actin gene. From more than 1000 eggs transplanted in each experiment, a considerable number of nuclear transplants developed to various embryonic stages showing stage- and tissue-specific expression of the donor genetic markers, although the expression was mosaic in many cases. Three and six of the transplanted eggs in the first and second experimental series (0.3 and 0.5%, respectively) hatched, and the hatchlings expressing the genetic markers survived for up to 3 weeks. The chromosome number varied among cells in a single transplant embryo. The results obtained in these experiments may help future cloning efforts in fish.     

Ultimate fate of rod outer segments in the retinal pigment epithelium.

To investigate the degradation pathway of rod outer segments (ROS) in vivo, we injected gold-labeled ROS into the subretinal space of rabbits using a pars plana approach. Histology and electron microscopy performed on the specimens 72 hr after ROS injection revealed that the retina over the injection site was reattached, the retinal pigment epithelial (RPE) cells were intact, and gold granules were localized inside melanin granules and melanosomes. These results indicate that, in RPE, in vivo degradation of ROS is associated with melanosomes.     

Human amniotic fluid stem cells attract osteoprogenitor cells in bone healing

Current treatments of large bone defects are based on autologous or allogenic bone transplantation. Human amniotic fluid stem cells (hAFSCs) were evaluated for their potential in bone regenerative medicine. In this study, hAFSCs were transduced with lentiviral vector harboring red fluorescent protein to investigate their role in the regeneration of critical-size bone defects in calvarial mouse model. To distinguish donor versus recipient cells, a transgenic mouse model carrying GFP fluorescent reporter was used as recipient to follow the fate of hAFSCs transplanted in vivo into Healos® scaffold. Our results showed that transduced hAFSCs can be tracked in vivo directly at the site of transplantation. The presence of GFP positive cells in the scaffold at 3 and 6 weeks after transplantation indicates that donor hAFSCs can recruit host cells during the repair process. These observations help clarify the role of hAFSCs in bone tissue repair.     

Uptake dynamics and retinal tolerance of phosphorothioate oligonucleotide and its direct delivery into the site of choroidal neovascularization through subretinal administration in the rat

This study aimed to investigate uptake dynamics and retinal tolerance of phosphorothioate oligonucleotides (PS-oligos) following subretinal injection. A fluorescent-labeled PS-oligo (FL-oligo) with random sequence was administered into the subretinal space of rat by transsclera-choroid-retinal pigment epithelium (RPE) injection at doses of 0.129, 1.29, and 12.9 microg in 2.0 microl solution. The uptake dynamics were evaluated by fundus fluorescent photography in real time and by fluorescence microscopy using flat mounts and cryosections. Immunophenotyping for CD4+, CD8+ cytotoxic lymphocytes, and CD68+ macrophages was performed to assess cellular infiltration in the retina. In addition, the FL-oligo was injected subretinally in a rat model of choroidal neovascularization (CNV) for direct delivery into the site of CNV. Subretinal administration of FL-oligo resulted in both dose-dependent and time-dependent distribution in the retina, where it accessed the RPE and all layers of the neuroretina. CD4+, CD8+ cytotoxic lymphocytes, and CD68+ macrophages were observed at the site of needle penetration. However, in areas far from the injection site where the FL-oligo appeared strongly, cellular infiltration was absent, and the retinal morphology was preserved very well. The FL-oligo was successfully delivered into the site of intense laser photocoagulation. It was predominantly localized to the RPE, macrophages, and some choroid cells and remained detectable for at least 56 days after injection. Our results demonstrate for the first time that subretinal injection efficiently introduced PS-oligo into the RPE and neuroretina with an acceptable level of safety. Subretinal administration of antiangiogenic oligonucleotides may hold great potential for the treatment of CNV.