从原始生殖细胞分离克隆鸡胚胎生殖细胞的研究

从孵化 5 5天的鸡胚生殖腺中分离得到大量原始生殖细胞 (PGCs)集落 ,这些集落的细胞经多次克隆传代具有胚胎生殖细胞 (EG)的诸多特征 ,如有连续传代的能力 (传至第 9代 ) ,细胞集落有典型鸟巢状结构 ,PAS染色阳性 ,AKP染色阳性 ,在无饲养层无分化抑制因子LIF时可以自发分化成几种细胞类型 ,包括成纤维细胞、神经细胞、自律细胞等 ,悬浮培养时具有形成类胚体的能力。上述发现表明该细胞具EG细胞的诸多特性 ,为类EG细胞     

原始生殖细胞体外培养及应用研究

原始生殖细胞是来源于胚胎生殖嵴的一类具有多向分化潜能的干细胞,其形态、细胞表面标志、分化潜能均与来源于囊胚内细胞团的干细胞相似.在饲养细胞层和多种生长因子的共同作用下,可保持原生殖细胞在体外不断增殖而不分化,最终建立EG细胞系.本文就原始生殖细胞体外培养,建立EG细胞系及其应用前景作一综述.     

鸡胚胎生殖细胞在鼠胚成纤维细胞饲养层上的生长

目的:探讨以鼠胚成纤维细胞为饲养层分离、培养鸡胚胎生殖细胞的方法和条件。方法:分离、培养12.5～13.5d鼠胚成纤维细胞。分离孵化5.5d鸡胚原始生殖细胞,原代培养时不使用饲养层,与性腺基质细胞共培养;继代培养时将其置于鼠胚成纤维细胞饲养层上,在含生长因子、分化抑制因子的培养体系中培养胚胎生殖细胞。结果:鼠胚成纤维细胞可连续传代18代以上(4个月),3～15代细胞可以用作饲养层细胞。分离的鸡胚胎生殖细胞在饲养层上可增殖形成典型胚胎生殖细胞集落,并能连续在体外培养超过9代。集落未分化标志高碘酸希夫反应(PAS)呈强阳性,体外分化实验表明胚胎生殖细胞具有多能性。结论:用鼠胚成纤维细胞作为饲养层能获得可连续增殖的胚胎生殖细胞。     

猪原始生殖细胞生物学特性的研究

胚胎生殖细胞（embryonic germ cell,EGC）是由胎儿原始生殖细胞（primordial germ cell,PGC）经体外驯化培养获得的一种多潜能干细胞。研究猪PGC生物学特性对于建立猪EGC及了解猪生殖细胞发育机制具有重要意义。该研究以原代培养的猪PGC为对象,探讨了其生长行为特征及其重编程过程中多能性、生殖系标志基因的表达模式。结果显示,26 d胚胎生殖嵴分离的PGC呈碱性磷酸酶阳性,细胞体积及核质比较大;体外培养初期呈现出较强的增殖及迁移能力,培养第5 d细胞增殖达到平台期,此时克隆高表达Oct4、Sox2、Nanog、c-Myc、Klf4和Ifi tm3（P〈0.05）,低表达Blimp1（P〈0.05）,Nanos1和Stella的表达水平与猪胎儿成纤维细胞无差异;猪PGC形成的原代克隆已经具有多向分化潜能。     

建立高效表达猪LIF的猪胚胎成纤维细胞系

该文目的是建立高效表达重组猪白血病抑制因子(leukemia inhibitory factor,LIF)的猪胚胎成纤维细胞(porcine embryonic fibroblasts,PEF)系PEF-p LIF,为下一步辅助建立和培养猪nave胚胎干细胞奠定基础。以猪胚胎成纤维细胞的总RNA为模板,利用RT-PCR的方法扩增猪白血病抑制因子基因(LIF),将LIF c DNA连接到真核表达载体p CAGDNA3的启动子下游,构建LIF基因真核表达载体p CAGDNA3-p LIF;利用核转染的方法将p CAGDNA3-p LIF质粒转入PEF;对转染细胞进行G418筛选,得到稳定高效表达重组猪LIF的PEF-p LIF;利用RT-PCR、Western blot鉴定PEF-p LIF中LIF基因及LIF表达情况;使用PEF-p LIF细胞作为饲养层培养小鼠胚胎干细胞,通过对小鼠胚胎干细胞进行碱性磷酸酶染色及细胞免疫荧光染色,对PEF-p LIF维持干细胞干性功能进行初步验证。实验结果显示,成功构建了真核表达载体p CAGDNA3-p LIF;并将其成功转入PEF中,获得高效表达重组猪LIF的PEF-p LIF;以PEF-p LIF作为饲养层成功培养克隆形态正常的小鼠胚胎干细胞。该研究表明,稳定高效表达重组猪LIF蛋白的猪胚胎成纤维细胞系PEF-p LIF可作为饲养层维持小鼠胚胎干细胞的未分化状态,可为下一步建立及培养猪nave胚胎干细胞提供条件。     

小鼠生殖细胞的胚胎发育

本文综述了近年来小鼠胚胎发育过程中生殖细胞的起源、迁移与增殖、性别分化及其基因组修饰等方面的研究进展。小鼠生殖细胞在7~7.5dpc时由原始生殖细胞（PGC）演变而来,至12.5dpc时PGC全部迁移进入生殖嵴,到13.5dpc时停止分裂。Steel/c-kit信号途径在PGC迁移过程中起重要作用。生殖细胞的性别主要是由生殖腺中体细胞的微环境决定的。Y染色体上存在精子形成所必需的基因。生殖细胞的全基因组范围的重新甲基化晚于胚胎体细胞的重新甲基化,到18.5dpc时才完成。雌性生殖细胞的X染色体重新活化在14.5~15.5dpc时完成,并且与生殖嵴的性别分化无关。 Abstract:This paper reviewed the recent progress of the origin,migration and proliferation,sex determination,and genomic modification of murine germ cells during its embryonic development. Murine germ cells originate from primordial germ cells at about 7~7.5dpc. Then PGCs migrated into germinal ridge at about 12.5dpc during which Steel/c-kit signal pathway plays important roles and stopped division at 13.5dpc. The sex of germ cells was mainly determined by the soma microenvironment in the gonad. And there are essential genes for sperm formation on the Y chromosome. The de novo methylation of murine germ cells was much later than soma cells and was completed at about 18.5dpc. The X chromosome reactivation of female germ cells was finished at about 14.5~15.5dpc which was independent of sexual differentiation of germinal ridge.     

牛胚胎生殖细胞的分离与培养

胚胎生殖细胞 (Embryonicgermcells,EG)是由生殖嵴原始生殖细胞 (Primordialgermcells,PGCs)中分离得到的一种未分化而多潜能的干细胞。牛EG细胞的研究在EG细胞核移植、转基因及建立生物反应器方面具有广阔的应用前景。本研究从 2 9- 70日龄牛胎儿PGCs分离得到EG细胞 ,经过抑制分化培养 ,其中一个细胞系传至 6代。所分离得到的EG细胞具有典型的EG细胞形态 ,AP及PAS染色呈阳性 ,核型正常 ,同时观察到这些细胞在体外进行自发性分化 ,可形成类胚体、成纤维样细胞及神经样细胞     

建立鸡EPGCs单细胞克隆株初探

目的探索鸡EPGCs单细胞克隆建立细胞系的可能性,并对其生物学特性进行鉴定。方法采取19期和28期的鸡EPGCs,体外培养传至第4代的细胞聚合体,用胰酶消化将细胞分散成单细胞悬液,将单个细胞接种至96孔板,每个孔内接种1个细胞,生长出的细胞集落用胶原酶消化传代,细胞化学法和免疫荧光法检测多向分化细胞的表面标志物;常规染色体核型检查。结果接种的288个单细胞中有9个扩增,其中7个传至第2代,2个传至第4代,克隆形成率为3.1%。扩增出的2~4代单细胞克隆能稳定增殖不分化,具有正常二倍性染色体核型、碱性磷酸酶阳性、阶段特异性胚胎抗原(SSEA)-1等特征性细胞表面标志物呈阳性;离体情况下具有形成类胚体和类上皮样细胞的能力。结论建立鸡EPGCs单细胞克隆细胞系是可行的,其生物学特性稳定。     

小鼠胚胎干细胞在六种培养体系的培养观察

目的　观察小鼠胚胎干细胞在六种培养体系中的生长情况。方法　小鼠胚胎干细胞 (ESD3细胞株 )在以下六种培养体系中培养 :1 .原代小鼠胚胎成纤维细胞 (MEF)有血清培养 ,2 .MEF无血清培养 ,3.SNL细胞有血清培养 ,4.LIF(白血病抑制因子 )有血清无饲养层培养 ,5.LIF无血清无饲养层培养 ,6.大鼠肝细胞 (BRL)条件培养基培养。经体外培养 1 0代后 ,观察其克隆形态 ,同时进行碱性磷酸酶检测并将ES细胞接种于裸小鼠皮下 ,观察ESD3的未分化状态和多潜能性。结果　六种培养体系培养的ESD3具有典型的ES细胞克隆形态 :巢状 (集落状 )隆起生长 ,边缘清楚 ,表面平滑 ,结构致密 ;AKP强阳性 ;裸小鼠体内形成了由多种组织构成的畸胎瘤。结论　六种培养体系均能支持ESD3生长 ,并能保持其未分化性和多潜能性 ,为ES细胞的应用研究奠定了良好的基础。     

中国小型猪胚胎生殖细胞的培养和建系

首次报道分别从28天和27天中国小型猪胚胎生殖嵴的原始生殖细胞培养和建立了两株胚胎生殖细胞系(embryonic germ cells,EG cells),各命名为BPEGl和BPEG2。根据它们的生长形态、细胞专一性标志以及体内、外分化等特征,证明了它们具有多能性的特性。这些猪EG细胞具有潜在的应用前景。     

Identification and migration of primordial germ cells in Atlantic salmon,Salmo salar: Characterization of Vasa,Dead End,and Lymphocyte antigen 75 genes

No information exists on the identification of primordial germ cells (PGCs) in the super‐order Protacanthopterygii, which includes the Salmonidae family and Atlantic salmon (Salmo salar L.), one of the most commercially important aquatic animals worldwide. In order to identify salmon PGCs, we cloned the full‐length cDNA of vasa, dead end (dnd), and lymphocyte antigen 75 (ly75/CD205) genes as germ cell marker candidates, and analyzed their expression patterns in both adult and embryonic stages of Atlantic salmon. Semi‐quantitative RT‐PCR results showed that salmon vasa and dnd were specifically expressed in testis and ovary, and vasa, dnd, and ly75 mRNA were maternally deposited in the egg. vasa mRNA was consistently detected throughout embryogenesis while dnd and ly75 mRNA were gradually degraded during cleavages. In situ analysis revealed the localization of vasa and dnd mRNA and Ly75 protein in PGCs of hatched larvae. Whole‐mount in situ hybridization detected vasa mRNA during embryogenesis, showing a distribution pattern somewhat different to that of zebrafish; specifically, at mid‐blastula stage, vasa‐expressing cells were randomly distributed at the central part of blastodisc, and then they migrated to the presumptive region of embryonic shield. Therefore, the typical vasa localization pattern of four clusters during blastulation, as found in zebrafish, was not present in Atlantic salmon. In addition, salmon PGCs could be specifically labeled with a green fluorescence protein (GFP) using gfp‐rt‐vasa 3′‐UTR RNA microinjection for further applications. These findings may assist in understanding PGC development not only in Atlantic salmon but also in other salmonids. Mol. Reprod. Dev. © 2013 Wiley Periodicals, Inc.     

Primordial germ cell-somatic cell partnership: a balancing cell signaling act

Recent studies demonstrate that the normal progression of the germ cell lineage during gonadogenesis involves a delicate balance of primordial germ cell survival and death factors generated by surrounding somatic cells. This balance operates in a different fashion in females and males. The fine tuning primordial germ cell specification in the wall of the yolk sac, migration through the hindgut and dorsal mesentery, and colonization in the urogenital ridges involves the temporal and spatial activation of the following signaling pathways: Primordial germ cell specification involves bone morphogenetic proteins 2, 4 and 8b, and their migration is facilitated by the c-kit receptor-ligand duet. When colonization occurs: (1) neuregulin-beta ligand is expressed and binds to an ErbB2-ErbB3 receptor tyrosine kinase heterodimer on primordial germ cells; (2) Vasa, an ortholog of the Drosophila gene vasa, member of an ATP-dependent RNA helicase of the DEAD (Asp-Glu-Ala-Asp)-box family protein is also expressed by primordial germ cells; (3) Bcl-x (cell survival factor) and Bax (cell death factor) join forces to modulate the first burst of primordial germ cell apoptosis; (4) Cadherins, integrins, and disintegrins bring together primordial germ cells and somatic cells to organize testis and ovary. Information on other inducers of primordial cell survival, such as TER (teratoma) factor, is beginning to emerge.     

Directed neural differentiation of duck embryonic germ cells

Although the avian primordial germ cells (PGCs) have been used to produce transgenic birds, their characteristics largely remain unknown. The isolation, culture, biological characterization, and directed neural differentiation of duck EG cells were assayed in this study. The Results showed that the EG cells were got by isolating embryonic gonad and surrounding tissue from 7-day-old duck embryo. The PGCs co-cultured with their gonadal somatic cells were well grown. After passaging, the EG cells were incubated in medium with cytokines and Mitomycin C on inactivated duck embryonic fibroblasts (DEFs) feeder layers. After several passages, alkaline phosphatase (ALP) and periodic acid-Schiff (PAS) resulted positive, cellular markers detection positive for SSEA-1, SSEA-4, TRA-1-60, and TRA-1-81. Karyotype analysis showed the EG cells kept diploid condition and the hereditary feature was stable in accordance with varietal characteristics of duck. These cells grew continuously for 11 passages on DEFs. Under induction of medium with BME, RA, and IBMX, the EG cells lost undifferentiated state, large amount of neural cells appeared with the formation of neural cells networks. Special Nissl body was found by toluidine blue stain after induced for 7 days. Immunofluorescence staining results indicated that differentiated EG cells expressed Nestin, NSE, and GFAP positive. The expression of Nestin, NSE, and GFAP mRNA were positive by RT-PCR. The results revealed that RA can obviously promote the directed differentiation of duck EG cells into neural lineage. The duck EG cells will be useful for the production of transgenic birds, for cell replacement therapy and for studies of germ cell differentiation.     

Germ cell nuclear antigen (GCNA1) expression does not require a gonadal environment or steroidogenic factor 1: Examination of GCNA1 in ectopic germ cells and in Ftz-f1 null mice

The germ cell lineage is first recognized as a population of mitotically proliferating primordial germ cells that migrate toward the gonadal ridge. Shortly after arriving at the gonadal ridge, the germ cells begin to initiate a commitment to gamete production in the developing gonad. The mechanisms controlling this transition are poorly understood. We recently reported that a mouse germ cell nuclear antigen 1 (GCNA1) is initially detected in both male and female germ cells as they reach the gonad at 11.5 days postcoitum (dpc). GCNA1 is continually expressed in germ cells through all stages of gametogenesis until the diplotene/dictyate stage of meiosis I. Since GCNA1 expression commences soon after primordial germ cells arrive at the gonadal ridge, we wanted to determine whether the gonadal environment was essential for induction of GCNA1 expression. By examining GCNA1 expression in germ cells that migrate ectopically into the adrenal gland, we determined that both the gonadal and adrenal gland environments allow GCNA1 expression. We also examined GCNA1 expression in Ftz-F1 null mice, which are born lacking gonads and adrenal glands. During embryonic development in the Ftz-F1 null mice, the gonad and most germ cells undergo apoptotic degeneration at about 12.5 dpc. While most of the germ cells undergo apoptosis without expressing GCNA1, a few surviving germs cells, especially outside the involuting gonad clearly express GCNA1. Thus, although the Ftz-F1 gene is essential for gonadal and adrenal development, induction of GCNA1 expression in germ cells does not require Ftz-F1 gene products. The finding that germ cell GCNA1 expression is not restricted to the gonadal environment and is not dependent on the Ftz-F1 gene products suggests that GCNA1 expression may be initiated in the germ cell lineage by autonomous means. Mol. Reprod. Dev. 48:154–158, 1997. © 1997 Wiley-Liss, Inc.     

Drosophila pericentrin‐like protein promotes the formation of primordial germ cells

Primordial germ cells (PGCs) are the precursors to the adult germline stem cells that are set aside early during embryogenesis and specified through the inheritance of the germ plasm, which contains the mRNAs and proteins that function as the germline fate determinants. In Drosophila melanogaster, formation of the PGCs requires the microtubule and actin cytoskeletal networks to actively segregate the germ plasm from the soma and physically construct the pole buds (PBs) that protrude from the posterior cortex. Of emerging importance is the central role of centrosomes in the coordination of microtubule dynamics and actin organization to promote PGC development. We previously identified a requirement for the centrosome protein Centrosomin (Cnn) in PGC formation. Cnn interacts directly with Pericentrin‐like protein (PLP) to form a centrosome scaffold structure required for pericentriolar material recruitment and organization. In this study, we identify a role for PLP at several discrete steps during PGC development. We find PLP functions in segregating the germ plasm from the soma by regulating microtubule organization and centrosome separation. These activities further contribute to promoting PB protrusion and facilitating the distribution of germ plasm in proliferating PGCs.     

Specification of human germ cell fate with enhanced progression capability supported by hindgut organoids

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大鼠睾丸曲细精管组织支持细胞/生殖细胞长期共培养与精子发生分析

睾丸体外生殖模型的发展为体外研究睾丸的精子发生分子机制和睾丸毒理学提供了实验工具。很多报道的模型都无法真正地模拟体内复杂的生化分子及功能性相互作用从而导致研究价值有限。该实验拟建立一个体外长期维持睾丸生殖细胞存在,并能持续产生精子细胞的支持细胞/生殖细胞共培养体系。体系中的支持细胞和生殖细胞均由曲细精管组织块迁移到培养皿上,在不添加任何生长因子的情况下维持体外精子发生至圆形精子细胞超过2个月。RT-PCR分析显示,共培养细胞稳定表达cdh1、scp3、tnp2;免疫荧光染色结果显示,CDH1、PLZF、SCP3以及SOX9阳性细胞存在。这些结果例证了体系中同时存在精原干细胞、精母细胞、精子细胞和支持细胞。简单高效的支持细胞/生殖细胞体外共培养体系可用于雄性生殖的分子机制和毒理学研究。     

Environmental factors for establishment of the dormant state in oocytes

Guaranteeing the sustainability of gametogenesis is a fundamental issue for perpetuating the species. In the mammalian ovary, sustainability is accomplished by keeping a number of oocytes “stocked” in the dormant state. Despite the evident importance of this state, the mechanisms underlying the oocyte dormancy are not fully understood, although it is presumed that both intrinsic and extrinsic factors are involved. Here, we review environmental factors involved in the regulation of oocyte dormancy. Consideration of the environmental factors illustrates the nature of the ovarian compartment, in which primordial follicles reside. This should greatly improve our understanding of the mechanisms and also assist in reconstitution of the dormant state in culture. Accumulating knowledge on the dormant state of oocytes will contribute to a wide range of research in fields such as developmental biology, reproductive biology and regenerative medicine.