通过显微注射法构建ES细胞(MESPU 13)嵌合小鼠

为了研究一个新建的小鼠胚胎干细胞系(ES细胞系)MESPU 13,我们将ES细胞显微注射到C57BL/6J小鼠的囊胚中构建嵌合鼠。在注射了2-9个ES细胞的136个囊胚中,127个囊胚(93%)经过3个小时的培养后重新出现囊胚腔。当把119个恢复的囊胚移植到假孕雌鼠的子宫内时,获得63只(52.9%)出生鼠。在59只存活到可以判断毛色阶段的小鼠中,有21只(35.6%)被判定为嵌合鼠。显示了该ES细胞系具有较高的嵌合能力。     

BALB／c小鼠胚胎干细胞系的建立及其嵌合体小鼠的获得

目的：建立BALB/c小鼠胚胎干细胞系,并用于制作嵌合体小鼠。方法：从BALB／c小鼠囊胚内分离培养内细胞团块。建系后,进行C57BL／6L小鼠受体囊胚腔注射,制作嵌合体小鼠,结果：建立了我国第一株BALB／c小鼠胚胎干细胞系,该细胞系具有典型的ES细胞形态,碱性磷酸酶强阳性,核型正常以及具有分化为三种胚层组织的能力,并已产生5只嵌合体小鼠,结论：建立的BALB／c小鼠胚胎干细胞系具有胚胎干细胞的各种特点,可用于体内外诱导分化研究,在进一步观察生殖系嵌合情况后,决定是否可应用于基因打靶等转基因动物的制作。     

通过胚胎干细胞途径获得的嵌合体小鼠中neo基因在各组织中的分布

为探讨小鼠胚胎干细胞参与早期胚胎发育的潜能,以neo基因作为目的基因进行了胚胎干细胞的转染,经G418的筛选,获得表达neo基因的单克隆细胞,挑取部分克隆扩大,进行小鼠囊胚腔注射,再重新植入小鼠子宫,共注射了60个囊胚,分别回输到5只假孕小鼠,在子代中得到了携带有neo基因的嵌合体小鼠。通过对嵌合体小鼠各组织PCR分析发现,neo基因可以在皮肤、肝脏、血液等多种组织中存在。     

胚胎融合制备四亲体小鼠

用两个不同基因型小鼠胚胎在其8细胞阶段进行体外胚胎融合。待融合的胚胎发育到囊胚期时,将其移植于另一种假孕雌鼠子宫腔内。约17天后发育成熟分娩得四亲体小鼠(Tetraparental mouse)。这种小鼠各组织和器官都含有两种来源的细胞群体。     

遗传修饰小鼠胚胎干细胞种系嵌合体小鼠的研制

利用显微注射的方法,分别将三株不同类型的经过遗传修饰的中靶ES细胞注射到C57BL/6J小鼠的囊胚中,通过胚胎移植将注射后的囊胚引入受体小鼠子宫中,分别获得了不同整合度的嵌合体小鼠,将高碳合度小鼠与C57BL/6J小鼠杂交,对这些仔鼠进行PCR及Southern鉴定的结果表明,三株修饰后的ES细胞均能整合入生殖系,得到了棕褐色子代鼠,表明获得了种系嵌合体小鼠。     

利用ES细胞建立可诱导的白血病模型

胚胎干细胞（embryonic stem cells,ESCs）是从囊胚的内细胞团分离出来的多潜能干细胞,具有多向分化的能力。将外源基因导入ES细胞建立转基因动物,对于研究外源基因的功能和调控具有一定的价值。载有外源性基因的病毒在感染ES细胞后,可通过囊胚注射获得具有胚系遗传的该转基因动物,并且这一外源基因可以稳定遗传和表达。该研究主要是利用携带hPML-RARα基因的慢病毒感染小鼠ES细胞系（R1）,获得携带该基因的ES细胞,感染后的ES细胞核型正常。在此基础上,将感染后的ES细胞经囊胚注射,获得了携带有hPML-RARα基因的3只嵌合小鼠,其中,有1只具有遗传特性。对嵌合体小鼠与C57杂交的后代给予强力霉素（doxycycline）处理,3天以后骨髓细胞hPML-RARα基因开始表达,这证明了在小鼠体内该外源基因表达的可诱导性。以上证实,已经成功利用ES细胞建立了可诱导的白血病转基因小鼠模型。     

远交系小鼠胚胎干细胞系的建立及嵌合鼠的获得

ES细胞（Embryonic Stcm Cells)是来源小鼠早期胚胎的多潜能干细胞,它可以在体外大量培养,并以单细胞的形式注射到早期胚胎里,发育为嵌合体,到目前为止,通常使用的129小鼠品系是来源于近交系（inbrcd)小鼠的胚胎。与之相比,远交系小鼠应当具有较强的生命力和抗病能力。曾有人报道过建成了远交系小鼠胚胎干细胞系,但是尚没有见到获得嵌合鼠的报道。有人甚至认为：由于不同品系小鼠所具有的遗传背景不同,有的小鼠不能建成ES细胞系。最近,本实验室在这方面做了有益的探索,成功地建成了远交系小鼠胚胎干细胞系,并在这里报导首例用远交小鼠胚胎干细胞系培育成功嵌合体小鼠。采用源于Swiss小鼠远交群的昆明（KM）品系小鼠囊胚建成了三个小鼠胚胎干细胞系（KE1,KE2,KE5)。核型正常率均达到70％以上。自第八代起分批存。复苏后,培养至第12代,消化成单细胞,通过囊胚显微注射,将其注射到615品系小鼠胚胎。在幸存的幼鼠中获得了一只来源于KE1细胞的嵌合鼠（Table1)。其毛色表现为受体鼠（615）的白色中嵌合有供体鼠（KM)黑褐色（Platc I-A）。嵌合鼠与受体鼠的杂交后代鼠中仍然出现了受体鼠的毛色类型（PlateI-B)。证明：ES细胞能嵌合到生殖腺并形成具有正常功能的配子,从而产生种系嵌合鼠。     

绿色荧光蛋白嵌合体小鼠的建立和鉴定

为研究嵌合体动物中供体胚胎干细胞 (ES)在宿主胚胎发育中的走向和定位 ,同时探讨绿色荧光蛋白(GFP)基因作为报告基因在转基因动物制作中的应用价值 ,本研究将pEGFP N1基因导入小鼠ES D3 细胞系 ,得到稳定表达GFP的胚胎干细胞亚系ES D3 GFP ,通过对昆明小鼠的囊胚腔注射 ,获得了 4只表达绿色荧光蛋白的嵌合体小鼠。其中 1只存活至成年 ,3只出生时死亡。荧光显像及组织PCR检测显示了绿色荧光蛋白在小鼠体内的嵌合情况。以绿色荧光为指标可实现活体水平的动态观察 ,本实验首次观察到以GFP为指标所示的机体嵌合情况与根据毛色嵌合推测的机体嵌合情况存在很大差异 ,以GFP为嵌合指标更加全面而准确 ;但不排除GFP对小鼠发育存在一定毒性的可能 ;另外 ,有结果显示供体ES细胞在宿主体内除了大片补丁状嵌合外 ,还存在细胞散在嵌合的情况 ,后者提示了在组织中利用GFP对ES细胞实施单细胞追踪和实时观察的可行性 ,为胚胎发育和疾病发生的相关研究提供了新的观察方法     

利用基因诱捕技术进行小鼠基因剔除的初步研究

对利用基因诱捕技术进行小鼠基因剔除做了初步的探索,为进一步应用该技术进行小鼠基因功能研究奠定了基础.利用基因诱捕载体转染小鼠ES细胞,获得了36株neo基因单拷贝整合的诱捕ES细胞,其中14株细胞表达有活性的β半乳糖苷酶.将3株诱捕ES细胞分别经显微注射引入到受体囊胚中,再植入假孕母鼠的子宫中使其发育成小鼠.两株细胞得到了程度不同的嵌合体小鼠,其中一株诱捕ES细胞整合至生殖系.利用质粒拯救实验获得了诱捕载体整合位点附近的基因组序列,通过序列比对发现被诱捕的基因可能是一个新基因.X-gal染色结果显示,该基因的表达局限于小鼠腹部及肢芽的部位.     

小鼠胚胎原始外胚层细胞的发育能力(英文)

本文利用胚泡注射技术研究了小鼠胚胎原始外胚层细胞(primitive ectoderm cells)的发育能力。从交配后第五天的129/SV-ter(灰色,GPI-1~a/~a)小鼠的胚胎中分离出原始外胚层细胞并将之注射到交配后第四天的C_(57)BL/6 J(黑色,GPI-1~b/~b)小鼠的胚泡腔内。经过显微操作后的胚泡被移回昆明白假孕鼠内发育,其出生率为83.3%,毛色嵌合体(chimeras)比例为100%。这些嵌合小鼠的磷酸葡萄糖异构酶(GPI-1)分析结果表明,注射的原始外胚层细胞参与了内、中、外三个胚层所衍生的组织和器官(如脑、血液、心脏、肾脏、生殖腺、肌肉、脾、旰等)的胚胎发生。嵌合体与C_(57)BL/6 J小鼠交配后所得的结果表明,原始外胚层细胞在嵌合体内能形成有功能的配子。上述结果说明,原始外胚层细胞与内细胞团(ICM)细胞、体外培养的胚胎干细胞(embryoderivedstem cells)一样,具有发育全能性。导入胚泡后,不仅能参与嵌合体中各种体细胞的分化,并且能经历配子发生产生有功能的雌雄配子。此外,本文还对胚泡注射技术进行了改进,改进后的方法不仅比已报道的各种方法简便,并且使注射嵌合体的比例提高到35.7%。     

Inhibitory influence of uterine secretions on mouse blastocysts decreases at the time of blastocyst activation

Uterine flushings from artificially 'pseudopregnant', pseudopregnant and pregnant mice and those with 'diapausing' embryos were tested for their effect on [3H]uridine incorporation by mouse blastocysts. An inhibitor of [3H]uridine incorporation was detected in the uterine fluid of the mice with diapausing embryos and the activity of the inhibitor was significantly reduced 6.25 h after an injection of oestrogen. This reduction of the inhibitory activity was dependent on the presence of blastocysts in utero, since a similar reduction did not occur in uterine fluids of pseudopregnant mice. The results support the suggestion that 'delayed' implantation in mice is caused by the presence of inhibitors of blastocyst metabolism and that activation, after an increase in oestradiol, is due to an embryo-dependent loss of activity of the inhibitors.     

Production of mouse by inter-strain inner cell mass replacement

The developmental ability of reconstructed blastocysts from C57BL/6 strain mouse inner cell masses (ICMs) and Kunming strain mouse trophoblasts was assessed. The procedure of ICM replacement was as follows: C57BL/6 ICMs were separated from the blastocysts using immunosurgery. A slit was made in the zona pellucida of a Kunming blastocyst to allow its ICM to extrude. The C57BL/6 ICM was injected into the Kunming blastocoele, and the extruded Kunming ICM was cut off. The reconstructed blastocysts were able to re-expand (77%) and hatch (27.3%) in vitro. A total of 64 reconstructed blastocysts and 124 Kunming blastocysts were co-transferred into the uteri of 11 pseudopregnant Kunming mice, and an ICM replacement offspring was born. The results indicate that reconstructed embryos obtained by inter-strain ICM replacement have the ability to develop to term. This technique may provide a method to solve the pregnancy failure in interspecific cloning.     

A comparative investigation on the potency of cells from the inner cell mass and trophectoderm of mouse blastocysts to produce chimeras

The ability of trophectoderm (TE) cells to produce chimeric mice (pluripotency) was compared with that of inner cell mass (ICM) cells. TE and ICM cells of blastocysts and hatching or hatched blastocysts derived from albino mice (CD-1, Gpi-1a/a) were aggregated with zona cut 8- to 16-cell stage embryos or injected into the blastocoele from non-albino mice (C57BL/6 x C3H/He, Gpi-1b/b). After transfer to pseudopregnant female mice, the contribution of the donor cells was examined by glucose phosphate isomerase (GPI) analysis of embryos, membrane and placenta at mid-gestation (Day 10.5 and 12.5) or by the coat color of newborn mice. In contrast to ICM cells, there was no contribution of TE cells in the conceptuses and no coat color chimeric young were obtained. After pre-labeling of TE cells with fluorescent latex microparticles, they were aggregated with embryos and the allocation of TE cells at the compacted morula and blastocyst stages was observed under a fluorescent microscope. Although the TE cells were observed attached onto the surface of the embryos at morula and blastocyst stages, unlike the ICM cells, they were not positively incorporated into the embryos. Thus, the pluripotency of TE cells from mouse blastocysts was not induced by the aggregation and injection methods.     

Mouse chimaeras developed from electrofused blastocysts: new evidence for developmental plasticity of the inner cell mass

Blastocysts obtained from mice differing in pigmentation (albino versus pigmented) and the isoforms of glucose phosphate isomerase (GPI 1A versus 1B) were electrofused and those containing a single chimaeric inner cell mass (ICM) were transferred to the uterus of pseudopregnant recipients. The pups were recovered on the 20(th) day by Caesarian section and fostered by females that had littered on the previous night or 24 h earlier. Altogether nine adult animals and two pups, which died soon after delivery, were available for GPI analysis. Between 9 and 13 organs/tissues were examined and the relative contribution of the GPI 1A and 1B isoforms was estimated using an electrophoretic GPI assay. Eight adult animals were overtly chimaeric and one was chimaeric in some internal tissues only. Eight mice were males: seven were fertile, one was infertile. The ninth adult mouse was a hermaphrodite. The fertile animals produced sperm of one genotype only, i.e. derived either from the albino or from the pigmented component. This is the first report showing that adult chimaeras can be produced from two combined blastocysts, provided that fusion of the adhering trophectoderm cells is first induced and the orientation of blastocysts enables the two ICMs to integrate into a single ICM. Our results suggest that in the preimplantation blastocyst, the organisation of the ICM remains labile thus making it possible for the fused blastocysts to establish new embryonic organisation and to develop into a single organism.     

Rat embryonic stem cells create new era in development of genetically manipulated rat models

Embryonic stem (ES) cells are isolated from the inner cell mass of a blastocyst, and are used for the generation of gene-modified animals. In mice, the transplantation of gene-modified ES cells into recipient blastocysts leads to the creation of gene-targeted mice such as knock-in and knock-out mice; these gene-targeted mice contribute greatly to scientific development. Although the rat is considered a useful laboratory animal alongside the mouse, fewer gene-modified rats have been produced due to the lack of robust establishment methods for rat ES cells. A new method for establishing rat ES cells using signaling inhibitors was reported in 2008. By considering the characteristics of rat ES cells, recent research has made progress in improving conditions for the stable culture of rat ES cells in order to generate gene-modified rats efficiently. In this review, we summarize several advanced methods to maintain rat ES cells and generate gene-targeted rats.     

Gene introduction into mouse blastocysts via “pricking”

It is a well-known phenomenon that cultured mammalian cells that have been pricked in the presence of foreign DNA can be transformed. This micromanipulation ‘pricking’ technique was applied to mouse blastocysts to determine whether uptake of exogenous DNA would occur in the embryos. The middle region of the inner cell mass (ICM) was pricked three times in each blastocyst in a medium containing a linearized plasmid DNA. When the 60 treated blastocysts were transferred to the uterine horns of pseudopregnant females, 30 developing fetuses (50%) at the mid-gestation stage were obtained. Twenty-two of the 30 fetuses (73%) had less than 1 copy of the foreign DNA per diploid cell, as revealed by polymerase chain reaction (PCR)-Southern analysis, a sensitive technique combined with Southern blot processing of the PCR products. The 8 other fetuses were negative for the foreign DNA. When blastocysts were pricked in the presence of vector DNA coupling E. coli β-galactosidase (β-gal) gene to a mouse metallothionein-I (MT-I) promoter and assessed for β-gal activity histochemically after 1 and 5 days of culture in the presence of 1 μM CdCI₂, at least 65% of the embryos exhibited β-gal activity mainly in the ICM region. These results indicate that mouse blastocysts can be transfected with a relatively high efficiency after pricking, and that the introduced gene expression occurs. This approach provides a means of mapping the regulatory elements of genes that are active in the mouse blastocyst ICM, and may be useful in investigating the fate of the ICM cells in an intact blastocyst by labeling them via pricking technique. © 1993 Wiley-Liss, Inc.     

Co-culture of mouse embryos with oviduct and uterine cells prepared from mice at different days of pseudopregnancy

Oviduct and uterine cell cultures were prepared from mice at different days of pseudopregnancy and their effects on the development of 1- and 8-cell mouse embryos in co-culture were examined. One-cell mouse embryos in co-culture with oviduct cells from 20 h to 120 h after hCG had a mean (+/- s.e.) cell number of 70.1 +/- 3.6, significantly (P less than 0.001) higher compared with those cultured in Whittingham's T6 medium supplemented with 5% fetal calf serum (T6 + 5% FCS) (30.4 +/- 1.6). Transfer of embryos, at 96 h after hCG, to synchronous pseudopregnant recipients showed that more embryos in oviduct co-culture formed fetuses than those cultured in T6 + 5% FCS. Co-culture of 1-cell embryos with uterine cells did not confer an advantage in cell numbers over T6 + 5% FCS. However, more 8-cell embryos formed blastocyst outgrowths after 100 h in co-culture with uterine cells prepared from mice at Day 3 of pseudopregnancy than with uterine cultures prepared from mice at Day 1 of pseudopregnancy or oviduct cells. In addition, there was further improvement when the Day 3 uterine co-cultures were supplemented with 1 or 10 ng progesterone/ml. These results highlight the importance of the oviduct and uterine cells during the different stages of preimplantation embryo development.     

Correlation of increased concentration of ovine endometrial cyclooxygenase 2 with the increase in PGE2 and PGD2 in the late luteal phase

The effect of intraoviductal embryos on endometrial receptivity was studied by intraendometrial and intrauterine embryo transfer. Five-week-old female ICR mice were mated after superovulation; a vaginal plug confirmed day 1 of pregnancy. On day 4 (90 h after hCG injection), blastocysts were collected and transferred to pseudopregnant female mice and to recipient mice in which the uterotubal junction had been ligated bilaterally on day 1 of pregnancy. Three embryos per uterine horn, a total of six embryos per recipient mouse at days 1-6, were transferred to the endometrium or uterine cavity and implantation and pregnancy rates were calculated. The implantation rate for intraendometrial embryo transfer to recipients of days 3, 5 and 6 was significantly higher for uterotubal junction-ligated mice (72.2, 20.8 and 9.7%, respectively) than for pseudopregnant mice (55.0, 8.3 and 0.0%, respectively). The implantation rate for intrauterine embryo transfer to recipients at days 2, 5 and 6 was significantly higher for uterotubal junction-ligated mice (11.1, 25.0 and 8.3%, respectively) than for pseudopregnant mice (0.0, 3.3 and 0.0%, respectively). Uterotubal junction-ligated mice achieved implantation and bore neonates by intrauterine embryo transfer on days 2 and 6, whereas no implantation was achieved in pseudopregnant mice. The difference in implantation rate could not be explained by a difference in progesterone concentration between the groups. The distribution of proliferating cells in the endometrium was also studied immunohistochemically by use of anti-proliferating cell nuclear antigen (PCNA) antibody in the recipient mice. PCNA-positive cells were more abundant in uterotubal junction-ligated mice and demonstrated a marked extension from the epithelium to the stroma over time, in contrast to those in pseudopregnant mice. These findings indicate that an intraoviductal embryo exerts a biological effect by sending a signal to the endometrial epithelium and stroma, thus facilitating endometrial receptivity to the embryo and improving the rate of implantation.     

Isolation of inner cell masses from mouse blastocysts by immunosurgery or exposure to the calcium ionophore A23187.

Two techniques have been evaluated for their use in routinely isolating inner cell masses from mouse blastocysts by destroying the trophectoderm. The most efficient method of immunosurgery was a 15-min incubation in a 1:50 dilution of rabbit anti-mouse spleen antiserum followed by a 30--60-min incubation in guinea pig complement (1:10). Alternatively, inner cell masses were isolated by incubating blastocysts in 10(-5) M calcium ionophore A23187 in medium devoid of calcium and magnesium ions. Inner cell masses re-exposed to immunosurgery or the ionophore were less susceptible to lysis than the trophectoderm had been. The presence of the zona pellucida reduced trophectoderm lysis by immunosurgery in antiserum dilutions greater than 1:100, but had no effect when in the presence of ionophore. Inner cell masses were consistently isolated from expanded blastocysts which had been collected 78 h after ovulation and cultured in vitro for 24 h before exposure to ionophore or immunosurgery, whereas blastocysts which had developed for the full 102 h in vivo were frequently unaffected.