逆转录病毒介导myostatin在鸡胚胎中的过表达与检测

鸡的胚胎已经成为发育生物学、免疫学和癌症等学科的重要实验模型之一。以鸡胚胎为实验模型,以鸡myostatin为靶基因,利用逆转录病毒介导和原位杂交技术相结合的方法来研究目的基因的鸡胚胎转导和检测分析。实验结果表明：逆转录病毒介导的目的基因myostatin能够有效整合到胚胎基因组中,且具有转录活性;胚胎原位杂交检测能够准确直观的反映病毒的整合部位和转入基因的表达水平。不但为进一步研究鸡myostatin基因在胚胎发育中的功能奠定基础,同时在方法上也进行了简单的优化尝试。     

Cdk2ap1在不同性别鸡胚中的表达

为研究通过抑制消减杂交筛选出的cdk2ap1基因在鸡胚胎发育过程中的表达, 设计cdk2ap1引物并通过 RT-PCR扩增cdk2ap1基因片段, 构建cdk2ap1/pGEM-T重组质粒。以构建的重组质粒为模板, 使用Sp6和T7 RNA聚合酶合成地高辛(dig )标记的正、反义RNA探针, 借助胚胎整体原位杂交技术研究了cdk2ap1在雌雄鸡胚中的表达。结果表明cdk2ap1基因在4.0 d两性胚胎的脑间质、菱脑、听囊、脊神经管、前肢等部位均有表达, 且在雄性鸡胚中的表达量高于雌性; 在雄性鸡胚的生殖脊、后肢部位中该基因有表达但在雌性胚胎对应部位却基本没有表达。鉴于该基因在雌雄鸡胚中的差异表达, 推测cdk2ap1基因在鸡胚性别分化及性腺发育过程中起一定调节作用。     

供体细胞在鸡—麻鸭嵌合体胚胎中的发育

用微注射法将鸡的PGCs注入到麻鸭的胚盘下腔中,用鸡W染色体DNA探针通过原位杂交对供体细胞在嵌合体胚胎中的发育作了研究,54个胚胎各器官都有不同程度的嵌合,其中肝脏的嵌合率最高,性腺最低,胚盘细胞移植可制备鸡－麻鸭的体细胞和种系嵌合体。     

鸡Vezf1基因RCAS干扰载体构建及鉴定

为研究Vezf1基因在鸡胚早期发育过程中的作用,构建了针对鸡Vezf1基因的RCAS病毒RNA干扰载体,分别在鸡胚细胞和胚胎水平对Vezf1基因实施沉默,通过Real-time PCR和原位杂交法检测目的基因m RNA表达水平。结果表明,基于RCAS病毒的干扰载体可以在鸡胚成纤维细胞和活体鸡胚中成功沉默Vezf1基因的表达。此研究为利用鸡胚模型深入了解Vezf1基因在早期发育过程中的作用提供了素材。     

人胎儿发育过程中核酸含量的变化

胚胎发育中核酸的测定是研究胚胎生化的重要方面之一。Davidson等曾报道鸡胚、羊胚各器官核酸的含量及鸡胚胎的心脏体外生长过程中核酸含量的变化。等研究了泥鳅卵发育过程中核酸的变动趋势,等测定了鱼在胚胎过程中的核酸。人胚胎核酸含量只见过零星报道。我们测定了24名胎儿9种脏器核酸的含量,胎儿的胎龄从12—40周,随着胎龄增长,比较了各脏器内核酸含量的变化趋势。     

转基因DT40细胞导入早期鸡胚后的分布及绿色荧光蛋白表达的研究

目的为了研究经过基因修饰的体细胞导入到禽类胚胎以后,供体细胞及外源基因是否能在受体胚胎中成活并且外源基因是否可以长期表达。方法筛选得到稳定整合绿色荧光蛋白基因的鸡DT40细胞作为外源蛋白的运载工具,通过血管微注射的方法将其导入到于38.5℃温度条件下孵化65～70 h的鸡胚中,并将操作后的鸡胚在原孵化条件下继续孵化。在孵化的不同时期取移植了DT40细胞的嵌合体胚胎在荧光显微镜下观察荧光细胞的存活与分布情况。并通过PCR以及免疫组织化学方法检测供体细胞在受体中的位置以及绿色荧光蛋白的表达情况。结果荧光标记的DT40细胞可以存活于受体不同的组织器官中,包括：脑、心脏、肝脏等。导入胚胎的整合外源基因的DT40细胞可以存活到胚胎出雏之前,并且外源基因能够正常表达。结论可以通过此方法将外源基因导入到受体中,并使目的蛋白在受体胚胎中持续表达,为胚胎期导入外源蛋白诱导免疫耐受的研究以及将转基因细胞移植到动物体内生产目的蛋白的研究提供科学依据和技术平台。     

不同饲养层对鸡胚胎干细胞培养效果的影响

目的:为探索鸡胚胎干细胞培养的优化条件,比较不同饲养层对鸡胚胎干细胞离体培养的效果。方法:用传至第2代的鸡胚成纤维细胞与鸭胚成纤维细胞,经丝裂霉素处理后制作饲养层,比较这2种饲养层以及不用饲养层对鸡胚胎干细胞离体培养效果的影响。结果:在以鸡胚成纤维细胞和鸭胚成纤维细胞作为饲养层的培养体系中,鸡胚胎干细胞均可保持良好的生长状态,而且2种饲养层对鸡胚胎干细胞克隆形成的影响差异不显著(P0.05)。结论:鸡胚成纤维细胞和鸭胚成纤维细胞均可作为较好的饲养层细胞用于鸡胚胎干细胞的离体培养。     

一种鸡胚胎心率记录的新方法

鸡胚胎是一种被广泛应用于发育生物学研究的实验材料。在以鸡胚胎为动物模型的各项研究工作中,心率常被看作是一个很重要的反应胚胎生理活动指标。本文详细介绍了一种侵入性的心电记录新方法,在正常的生理条件下通过记录鸡胚胎心电的变化来监测心率。首先在蛋壳上钻孔,将电极插入蛋内,然后通过放大器放大,A／D板转换,将心电信号输入电脑进行分析处理,提取与心率相关的信息。这种记录方式对胚胎损伤较小,不影响胚胎的正常发育;具有灵敏度高,操作简单,容易掌握等特点。     

人胎儿发育过程中核酸含量的变化

胚胎发育中核酸的测定是研究胚胎生化的 重要方面之一。Davidson等曾报道鸡胚、羊胚 各器官核酸的含量^[1]及鸡胚胎的心脏体外生长 过程中核酸含量的变化^[2].THMo中eeBa等研究 了泥鳅卵发育过程中核酸的变动趋势^[6], A13TXWEM 等测定了鱼在胚胎过程中的核酸^[5]。人 胚胎核酸含量只见过零星报道^[2]。我们测定了 24名胎儿9种脏器核酸的含量,胎儿的胎龄从 12-40周,随着胎龄增长,比较了各脏器内核 酸含量的变化趋势。     

转基因鸡的研究策略

转基因研究工作开展十几年来,成就斐然。转基因鸡的研究策略论述了生产转基因鸡的几种方法和鸡的基因组操作研究进展,并详细地阐述了转基因鸡胚胎的体外培养技术。指出：转基因鸡投入生产以前必须查明其表型改变对生态平衡的影响。     

The chicken as a model for embryonic development

The traditional strength of chicken embryos for studying development is that they are readily manipulated. This has led to some major discoveries in developmental biology such as the demonstration that the neural crest gives rise to almost the entire peripheral nervous system and the identification of signalling centres that specify the pattern of structures in the central nervous system and limb. More recently with the burgeoning discovery of developmentally important genes, chicken embryos have provided useful models for testing function. Uncovering the molecular basis of development provides direct links with clinical genetics. In addition, since many genes that have crucial roles in development are also expressed in tumours, basic research on chickens has implications for understanding human health and disease. Now that the chicken genome has been sequenced and genomic resources for chicken are becoming increasingly available, this opens up opportunities for combining these new technologies with the manipulability of chicken embryos and also exploiting comparative genomics.     

Gene transfer into chicken embryos as an effective system of analysis in developmental biology

Chicken embryos have been used as a model animal in developmental biology since the time of comparative and experimental embryology. Recent application of gene transfer techniques to the chicken embryo increases their value as an experimental animal. Today, gene transfer into chicken cells is performed by three major systems, lipofection, electroporation and the virus-mediated method. Each system has its own features and applicability. In this overview and the associated four minireviews, the methods and application of each system will be presented.     

High resolution,label‐free photoacoustic imaging of live chicken embryo developing in bioengineered eggshell

Chicken embryos have been proven to be an attractive vertebrate model for biomedical research. They have helped in making significant contributions for advancements in various fields like developmental biology, cancer research and cardiovascular studies. However, a non‐invasive, label‐free method of imaging live chicken embryo at high resolution still needs to be developed and optimized. In this work, we have shown the potential of photoacoustic tomography (PAT) for imaging live chicken embryos cultured in bioengineered eggshells. Laser pulses at wavelengths of 532 and 740 nm were used for attaining cross‐sectional images of chicken embryos at different developmental stages. Cross‐sections along different depths were imaged to gain knowledge of the relative depth of different vessels and organs. Due to high optical absorption of vasculature and embryonic eye, images with good optical contrast could be acquired using this method. We have thus reported a label‐free method of performing cross‐sectional imaging of chicken embryos at high resolution demonstrating the capacity of PAT as a promising tool for avian embryo imaging.     

Identification of transgene integration site and anatomical properties of fluorescence intensity in a EGFP transgenic chicken line

Transgenic birds are commonly used for time-lapse imaging and fate mapping studies in developmental biology. When researchers use transgenic birds expressing fluorescent protein, they need to understand the integration site of the transgene in the genome and the intensity of fluorescence in the tissues of interest. In this study, we determined the integration site of the transgene and fluorescence property of developing organs in our transgenic chicken line generated by lentivirus infection. The transgene was localized between exons 3 and 4 of MED27. Some homozygotes and heterozygotes appeared to be lethal at early embryonic stages. We performed histological analysis of EGFP expression in transgenic embryos at St. 14, 17, and 24 by immunohistochemistry with anti-GFP antibody on paraffin sections. Next, we cut cryosections and quantified direct EGFP intensity from the transgene in each tissue without performing immunohistochemistry. These results revealed that EGFP intensity in each tissue was unique in developing embryos and changed according to developmental stages. Finally, we demonstrated that EGFP-expressing cells in a micromass culture with co-culturing wild-type cells were clearly distinguishable via live cell imaging. These results provide essential information on the potential of our transgenic line and indicate that these transgenic chicken lines are useful for research associated with developmental biology.     

Establishment of Eimeria tenella (local isolate) in chicken embryos

Development of an in vitro Eimeria (E.) tenella model could be valuable as a tool for vaccine, coccidiostats or molecular biology research. 1.0 × 10,000 sporozoites per 0.1 mL were inoculated into the allantoic cavity of ten-day-old chicken embryos. The complete life-cycle of E. tenella was accomplished in eight-nine days at 37 °C and 70% humidity. The addition of 100 U insulin to the embryos could remarkably improve the output of oocysts. The development of the parasite within the embryos was systematically observed, allowing guidelines to be set regarding the appropriate times at which different developmental stages of the parasite may be sampled.     

The expression patterns of c-kit and Sl in chicken embryos suggest unexpected roles for these genes in somite and limb development

We have used whole-mount in situ hybridization to investigate the patterns of c-kit and Sl expression in stage 11-22 chicken embryos. Our analysis shows that c-kit and Sl are expressed quite differently in chicken embryos compared to the reported expression patterns of these genes in embryos of other taxa. Most notably, chicken c-kit is expressed in primordial germ cells as well as in the developing somite, the apical ectodermal ridge, and in the early foregut endoderm. Sl is expressed in the lateral and intermediate mesoderm and in extraembryonic membranes. These data suggest that chicken c-kit and Sl may play novel and unexpected roles in somitogenesis, limb development, and foregut development in avian embryos.     

Efficacy of production of reassortant of epidemic strains and cold-adapted influenza viruses in chicken embryo and MDCK cells

Reassortant strains for modern live influenza vaccines are prepared using growing chicken embryos. It is very important to switch manufacture of influenza vaccines from chicken embryos to cell cultures, especially due to the threat of future pandemic, when there will be need of big quantities of vaccine for immunization of all age groups. Efficacy of production of reassortant strains with 6:2 vaccine formulation of genome (6 internal genes from the donor of attenuation and 2 genes coding external antigens--hemagglutinin and neuraminidase--from epidemic strain) in MDCK cell culture, using standard techniques employed for production of the vaccine in chicken embryos, was studied. It was shown that yield frequency of aforementioned reassortants of influenza A viruses did not exceed 5.7% whereas in chicken embryos vaccine 6:2 reassortants were isolated with frequency of 4%. For influenza B viruses, yield of 6:2 reassortants in growing chicken embryos exceeded 67% whereas in MDCK cell culture we were unable to produce clones with required genome composition. Thus, existing method while effective for production of vaccine reassortants in chicken embryos is low effective for isolation of 6:2 reassortants in MDCK cell culture. Fundamentally new techniques are needed for production of reassortant strains for live influenza vaccine in cell culture.     

Integration of human mesenchymal stem cells into the Wolffian duct in chicken embryos

Developing animal embryos have been providing human mesenchymal stem cells (hMSCs) with an appropriate environment for their differentiation between species. We previously demonstrated that hMSCs transplanted into the metanephric mesenchyme region of rat embryos differentiate into kidney-specific cells. Here, we assessed whether hMSCs are competent to differentiate into precursors of the collecting duct system when they are transplanted into the ureteric bud progenitor region of chicken embryos that are easier to be manipulated and cultured than mammalian embryos. When chicken Pax2-expressing hMSCs were transplanted into the chicken ureteric bud progenitor region, they migrated caudally with the elongating Wolffian duct and then were integrated into the Wolffian duct epithelia. Also, chicken Pax2-expressing hMSCs started to express human LIM1 after their integration into the Wolffian duct epithelia. These results suggest that chicken Pax2-expressing hMSCs can be competent to differentiate into the Wolffian duct cells by the influence of chicken local signals.     

Gene transfer into chicken embryos by retrovirus vectors

While chickens have many properties that are advantageous for embryological studies, their genetic analysis has been restricted. However, by using retrovirus vector systems in combination with classical techniques of experimental developmental biology, it has recently become possible to analyze the function of genes involved in the development of this organism. Avian retrovirus vectors are unique in that they can be divided into two categories: replication-competent and replication-defective (replication-incompetent). By choosing the vectors correctly, there are many experimental applications of these vectors such as induction of constitutive (or regulated) gene expression in a restricted region of tissues, organs and embryos; cell lineage analysis; and formation of concentration gradients of morphogens in micromass cultures. In this paper, several retrovirus vectors available for the chicken will be introduced and their applications in developmental biology will be reviewed.