供体细胞类型对体细胞克隆牛生产效率的影响

建立了中国红系冀南黄牛颗粒细胞系(YGR)、Holstein奶牛颗粒细胞系(HGR)、Holstein奶牛不同个体的成年成纤维细胞系(AFB)以及Holstein奶牛同一个体的胎儿成纤维细胞系(FFB)和胎儿输卵管上皮细胞系(FOV). 以上述不同类型的体细胞为核供体, 进行了体细胞核移植, 共成功培育出12头体细胞克隆牛. 比较了不同类型供体细胞的重构胚的发育潜能, 结果表明: (ⅰ) YGR和HGR的重构胚的囊胚发育率(33.2% vs 35.1%)无显著差异(P > 0.05), 妊娠率分别为33.3%和30.2%, 产犊率分别为16.7%和11.6%; (ⅱ) Holstein奶牛不同个体AFB的重构胚的囊胚发育率(27.9% vs 39.4%)差异显著(P < 0.05), 妊娠率分别为36.2%和36.4%, 产犊率分别为14.9%和27.3%; (ⅲ) Holstein奶牛同一个体的FFB和FOV的重构胚的囊胚发育率(37.9% vs 41.5%)差异显著(P < 0.05), 妊娠率分别为45.7%和24.1%, 产犊率分别为22.9%和10.3%. 综合比较Holstein奶牛的4种体细胞(HGR, AFB, FFB和FOV)的重构胚的发育情况, 结果显示: 在体外发育阶段, FOV的重组胚的囊胚发育率(41.5%)最高, FFB (37.9%)和HGR (35.1%)次之, AFB(29.4%)最低, 三者之间差异显著(P < 0.05). 在体内发育阶段, 4种供体细胞克隆胚胎的妊娠率分别为30.2%, 36.2%, 45.7%和24.1%, 产犊率分别为11.6%, 17.2%, 22.9%和10.3%.     

Xist基因抑制对牛SCNT早期胚胎发育的影响

Xist是与X染色体失活相关的非编码基因,它在合子期基因组开始表达,是胚胎发育早期表达的第一个印记基因。探讨了特异性抑制Xist的TALER-REPRESSOR(TALER)载体转染到胎牛成纤维细胞对Xist基因的抑制作用,并以抑制Xist基因表达的细胞作为核供体制作克隆胚胎,研究Xist基因抑制对牛克隆胚早期发育的影响。结果显示,与对照组细胞相比,TALER载体将Xist相对表达量下调了93.85%,说明本试验设计的载体转染系统能够有效抑制Xist基因的表达。选取Xist抑制表达阳性的转染细胞用于体细胞核移植试验,克隆胚胎发育结果显示,试验组和对照组的卵裂率、8细胞发育率、桑葚胚发育率和囊胚发育率分别为78.8%vs 75.1%(P0.05,无显著差异)、54.4%vs 50.6%(P0.05,无显著差异)、12.3%vs 27.8%(P0.01,差异极显著)、0 vs 26.6%(P0.01,差异极显著)。综上所述,试实验设计的特异性抑制Xist表达的TALER载体可有效抑制雌性胎牛成纤维细胞中Xist的表达。供体细胞Xist这种基因下调可使克隆胚胎2-8细胞率略有提升,但囊胚期和桑葚胚率明显降低。因此,其机制尚待于进一步探讨。     

哺乳动物体细胞核移植表观遗传重编程研究进展

体细胞核移植(somatic cell nuclear transfer, SCNT)是唯一能赋予体细胞基因组全能性的生殖工程技术,对动物种质资源保存、畜牧业发展和生物医学研究等具有重大意义。尽管该技术已经取得了许多研究进展,但哺乳动物克隆胚胎的发育效率依然很低,严重限制其在畜牧业和生物医学上的应用。导致克隆胚胎发育效率低的主要原因是体细胞重编程错误或重编程不完全,主要表现为:印记基因Xist表达异常、DNA甲基化异常,组蛋白修饰异常等。本文简要介绍了体细胞核移植技术,系统总结了哺乳动物克隆胚胎发育效率低的主要影响因素,以期为提升体细胞克隆效率相关研究与实践提供理论参考。     

整合人lactoferrin基因的山羊体细胞支持核移植克隆胚的体外发育

克隆了人lactoferrin基因和山羊[[beta]]-casein基因5′端调控区, 构建了人lactoferrin的乳腺表达载体, 并将该载体利用脂质体介导转染了奶山羊胎儿成纤维细胞, 获得了稳定整合人lactoferrin基因的转基因体细胞克隆17个, 其中PCR和Southern Blot检测阳性的细胞克隆14个, 阳性率82.4%。以转基因体细胞为供体细胞进行了核移植, 获得了能够体外发育的山羊转基因克隆胚胎, 体内成熟卵母细胞来源的核移植囊胚率为64.8%, 体外成熟卵母细胞来源的核移植囊胚率为51.7%, 证明了山羊转基因体细胞能够支持克隆胚的进一步发育。     

体细胞核移植后表观遗传重编程的异常及其修复

体细胞核移植(Somatic cell nuclear transfer, SCNT)是指将高度分化的体细胞移入到去核的卵母细胞中发育并最终产生后代的技术。然而, 体细胞克隆的总体效率仍然处于一个较低的水平, 主要原因之一是由于体细胞供体核不完全的表观遗传重编程, 包括DNA甲基化、组蛋白乙酰化、基因组印记、X染色体失活和端粒长度等修饰出现的异常。使用一些小分子化合物以及Xist基因的敲除或敲低等方法能修复表观遗传修饰错误, 辅助供体核的重编程, 从而提高体细胞克隆效率, 使其更好地应用于基础研究和生产实践。文章对体细胞核移植后胚胎发育过程中出现的异常表观遗传修饰进行了综述, 并着重论述了近年来有关修复表观遗传错误的研究进展。     

人-牛异种克隆胚构建及其线粒体来源

通过人-牛异种核移植技术获得异种克隆囊胚, 便于在不消耗人类卵母细胞的情况下从异种克隆胚中分离出人类干细胞。通过透明带下注射法将人胎儿成纤维细胞和牛耳成纤维细胞分别注入去核牛卵母细胞中构建异种和同种胚胎, 并比较两者之间的融合率、卵裂率、8-细胞发育率以及囊胚率。并对处于2-细胞、4-细胞、8-细胞、桑椹胚、囊胚阶段的异种克隆胚的线粒体DNA来源进行检测。结果表明, 异种克隆胚体外各个阶段的发育率均低于同种克隆胚, 尤其是8-细胞到囊胚阶段的发育率, 以及囊胚率都显著低于同种克隆胚(P<0.05)。异种克隆胚在2-细胞到桑椹胚阶段检测到人、牛线粒体DNA共存, 囊胚阶段只检测到牛线粒体DNA。结果表明: 牛卵母细胞可以重编程人胎儿成纤维细胞, 完成异种克隆胚植入前的胚胎发育, 异种克隆胚由于核质相互作用的不谐调, 影响其发育能力, 使其囊胚率显著低于同种克隆胚。牛线粒体DNA存在于植入前异种胚胎发育的各个阶段。异种克隆胚胎用于人类胚胎干细胞分离具有可行性。     

DNA甲基化修饰与体细胞核移植的关系

成功的体细胞核移植（somatic cell nuclear transfer,SCNT）有赖于供体细胞的基因组通过重编程恢复到支持胚胎发育的全能性状态。但是,相比起自然受精后发生的重编程来说,要诱导一个已经分化的供体细胞重编程为全能性状态,往往在时间上和程度上都是迟滞的和不完全的。同时,DNA甲基化状况又是影响克隆胚胎发育和基因表达的关键因素之一。因此,深入研究主导DNA甲基化修饰的分子机理,探讨DNA去甲基化在供体细胞重编程过程中扮演的角色,从而进一步提高供体细胞重编程效率,提高克隆胚的发育潜能,这对于体细胞核移植效率的提高具有重要的意义。     

Mash2基因在体细胞克隆牛肺脏中DNA甲基化状态分析

体细胞核移植(体细胞克隆)技术在动物生产、医药工业、治疗性克隆以及对珍稀濒危动物的拯救有重要意义,然而克隆效率低下以及克隆动物发育异常,严重制约了克隆技术的发展和应用．在体细胞核克隆中,供体核来自高度分化了的体细胞,发生在核移植后几小时内供体核的重编程,决定了克隆胚胎的发育能力．印记基因是由等位基因表观遗传修饰的不对称导致的基因表达具有亲本选择性,而DNA甲基化是调控印记的一个主要方式．印记基因Mash2在胚胎发育和器官形成过程中起着非常重要的作用．为了探求核移植过程中Mash2基因DNA 甲基化的表观重编程是否充分,利用亚硫酸氢盐测序法对出生48 h内死亡的体细胞核移植牛和正常对照牛肺脏中Mash2基因的DNA甲基化状态进行分析．结果显示,尽管位于Mash2基因启动子和第一个外显子处的CpG岛在正常牛和克隆牛中甲基化水平都不高(20.04%,5.55%),但克隆组的甲基化水平仍显著低于正常对照组 (P < 0.05)．甲基化模式正常组中9N3有5种不同的形式,9N4仅1种;而克隆组9C3和9C5也分别是1种．推测Mash2基因的异常DNA甲基化很可能是导致克隆牛肺脏发育异常的一个重要原因．     

哺乳动物DNA甲基化及其在体细胞诱导重编程中的作用

诱导多能干细胞(Induced pluripotent stem cell, iPS)技术提供了将终末分化的细胞逆转为多潜能干细胞的可能, 在干细胞基础理论研究和再生医学中具有重要意义。然而, 目前体细胞诱导重编程方法效率极低, 常发生不完全的重编程。研究表明, 在不完全重编程的细胞中存在体细胞的表观遗传记忆, 而DNA甲基化作为相对长期和稳定的表观遗传修饰, 是影响重编程效率和iPS细胞分化能力的重要因素之一。哺乳动物DNA甲基化是指胞嘧啶第五位碳原子上的甲基化修饰, 常发生于CpG位点。DNA甲基化能够调节体细胞特异基因和多能性基因的表达, 因此其在哺乳动物基因调控、胚胎发育和细胞重编程过程中发挥着重要作用。此外, 异常DNA甲基化可能导致iPS细胞基因印记的异常和X染色体的失活。文章重点围绕DNA甲基化的机制、分布特点、及其在体细胞诱导重编程中的作用进行了综述。     

山羊克隆胎儿不同组织中H19基因CpG岛甲基化模式及表达量检测

表观重编程异常是核移植胚胎发育异常的重要原因。为了研究克隆山羊胎儿不同组织中H19基因CpG岛甲基化水平和相对表达量,本实验运用亚硫酸盐法和荧光实时定量PCR法分别检测了死亡克隆山羊胎儿和同期普通山羊胎儿(对照组)肝脏、胎盘、肾脏、肺脏和心脏组织中H19基因CpG岛甲基化水平和mRNA的相对表达量。结果表明,克隆山羊胎儿胎盘组织中H19基因第5个CpG岛的甲基化水平显著高于对照组(70%vs49.41%,P0.05),H19基因相对表达量显著低于对照组(883.3vs1264.5,P0.05);肺脏组织甲基化水平显著低于对照组(63.53%vs88.24%,P0.05),相对表达量显著高于对照组(1003.4vs515.5,P0.05);其他各组差异不显著(P0.05)。结果说明,H19基因在克隆山羊胎儿部分组织中DNA甲基化重编程异常,而且这种异常影响H19基因的正常表达,这也可能是导致克隆动物死亡的重要因素之一。     

免疫荧光染色检测克隆牛X染色体组蛋白H3 Lys 4 二甲基化修饰

利用免疫荧光染色, 检测胎儿成纤维细胞(FFB)和输卵管上皮细胞(FOV)来源的克隆牛X中期染色体组蛋白H3 K4m2修饰状况。结果发现, 这两种细胞系来源的克隆牛耳组织细胞系X染色体H3 K4m2修饰与供体核FFB细胞系和常规繁殖牛耳组织细胞系的修饰基本一致, 而与供体核FOV细胞系有较大差异。     

Epigenetic marks in cloned rhesus monkey embryos: comparison with counterparts produced in vitro

Until now, no primate animals have been successfully cloned to birth with somatic cell nuclear transfer (SCNT) procedures, and little is known about the molecular events that occurred in the reconstructed embryos during preimplantation development. In many SCNT cases, epigenetic reprogramming of the donor nuclei after transfer into enucleated oocytes was hypothesized to be crucial to the reestablishment of embryonic totipotency. In the present study, we focused on two major epigenetic marks, DNA methylation and histone H3 lysine 9 (H3K9) acetylation, which we examined by indirect immunofluorescence and confocal laser scanning microscopy. During preimplantation development, 67% of two-cell- and 50% of eight-cell-cloned embryos showed higher DNA methylation levels than their in vitro fertilization (IVF) counterparts, which undergo gradual demethylation until the early morula stage. Moreover, whereas an asymmetric distribution of DNA methylation was established in an IVF blastocysts with a lower methylation level in the inner cell mass (ICM) than in the trophectoderm, in most cloned blastocysts, ICM cells maintained a high degree of methylation. Finally, two donor cell lines (S11 and S1-04) that showed a higher level of H3K9 acetylation supported more blastocyst formation after nuclear transfer than the other cell line (S1-03), with a relatively low level of acetylation staining. In conclusion, we propose that abnormal DNA methylation patterns contribute to the poor quality of cloned preimplantation embryos and may be one of the obstacles to successful cloning in primates.     

Establishment of Trophectoderm Cell Lines from Buffalo (Bubalus bubalis) Embryos of Different Sources and Examination of In Vitro Developmental Competence,Quality, Epigenetic Status and Gene Expression in Cloned Embryos Derived from Them

Despite being successfully used to produce live offspring in many species, somatic cell nuclear transfer (NT) has had a limited applicability due to very low (>1%) live birth rate because of a high incidence of pregnancy failure, which is mainly due to placental dysfunction. Since this may be due to abnormalities in the trophectoderm (TE) cell lineage, TE cells can be a model to understand the placental growth disorders seen after NT. We isolated and characterized buffalo TE cells from blastocysts produced by in vitro fertilization (TE-IVF) and Hand-made cloning (TE-HMC), and compared their growth characteristics and gene expression, and developed a feeder-free culture system for their long-term culture. The TE-IVF cells were then used as donor cells to produce HMC embryos following which their developmental competence, quality, epigenetic status and gene expression were compared with those of HMC embryos produced using fetal or adult fibroblasts as donor cells. We found that although TE-HMC and TE-IVF cells have a similar capability to grow in culture, significant differences exist in gene expression levels between them and between IVF and HMC embryos from which they are derived, which may have a role in the placental abnormalities associated with NT pregnancies. Although TE cells can be used as donor cells for producing HMC blastocysts, their developmental competence and quality is lower than that of blastocysts produced from fetal or adult fibroblasts. The epigenetic status and expression level of many important genes is different in HMC blastocysts produced using TE cells or fetal or adult fibroblasts or those produced by IVF.     

Precise recapitulation of methylation change in early cloned embryos

Change of DNA methylation during preimplantation development is very dynamic, which brings this term to the most attractive experimental target for measuring the capability of cloned embryo to reprogram its somatic genome. However, one weak point is that the preimplantation stage carries little information on genomic sequences showing a site-specific re-methylation after global demethylation; these sequences, if any, may serve as an advanced subject to test how exactly the reprogramming/programming process is recapitulated in early cloned embryos. Here, we report a unique DNA methylation change occurring at bovine neuropeptide galanin gene sequence. The galanin gene sequence in early bovine embryos derived by in vitro fertilization (IVF) maintained a undermethylated status till the morula stage. By the blastocyst, certain CpG sites became methylated specifically, which may be an epigenetic sign for the galanin gene to start a differentiation programme. The same sequence was moderately methylated in somatic donor cell and, after transplanted into an enucleated oocyte by nuclear transfer (NT), came rapidly demethylated to a completion, and then, at the blastocyst stage, re-methylated at exactly the same CpG sites, as observed so in normal blastocysts. The precise recapitulation of normal methylation reprogramming and programming at the galanin gene sequence in bovine cloned embryos gives a cue for the potential of cloned embryo to superintend the epigenetic states of foreign genome, even after global demethylation.     

Analysis of development-related gene expression in cloned bovine blastocysts with different developmental potential

The high incidence of abnormalities in cloned calves is a most serious problem for bovine somatic cell nuclear transfer (NT) technology. Because there is little information on the differences in mRNA expression in cloned blastocysts with donor cells of different sex and origin, we compared development-related gene expression in two types of cloned bovine blastocysts with different potentials to develop into normal calves, a female adult cumulus cell line (high potential to develop into live calves) and a male fibroblast cell line (low potential to develop into live calves) to examine the correlation between the normality of cloned calves and blastocyst mRNA expression patterns. We analyzed 12 genes involved in apoptosis, growth factor signaling, metabolism, and DNA methylation in blastocysts originating from two types of donor cells and in vitro-fertilized blastocysts using quantitative real-time polymerase chain reaction. Expression of the pro-apoptotic Bax gene and anti-apoptotic Bcl-2 and Glut-1 genes in fibroblast-derived blastocysts was significantly higher than in cumulus cell-derived and in vitro-fertilized blastocysts. The high Bcl-2 and Glut-1 gene expression suggests that some embryonic cells with damaged DNA in fibroblast-derived blastocysts are not removed, and their descendants later manifest abnormal placenta or fetus formation. Transfer of pre-selected cloned blastocysts into recipients is required, however, to determine whether the expression pattern of these apoptosis-related genes reflects differences in the potential to develop into normal calves.     

The analysis of telomere length and telomerase activity in cloned pigs and cows

Inefficiency in the production of cloned animals is most likely due to epigenetic reprogramming errors after somatic cell nuclear transfer (SCNT). In order to investigate whether nuclear reprogramming restores cellular age of donor cells after SCNT, we measured telomere length and telomerase activity in cloned pigs and cattle. In normal pigs and cattle, the mean telomere length was decreased with biological aging. In cloned or transgenic cloned piglets, the mean telomere length was elongated compared to nuclear donor fetal fibroblasts and age-matched normal piglets. In cloned cattle, no increases in mean telomere length were observed compared to nuclear donor adult fibroblasts. In terms of telomerase activity, significant activity was observed in nuclear donor cells and normal tissues from adult or new-born pigs and cattle, with relatively higher activity in the porcine tissues compared to the bovine tissues. Cloned calves and piglets showed the same level of telomerase activity as their respective donor cells. In addition, no difference in telomerase activity was observed between normal and transgenic cloned piglets. However, increased telomerase activity was observed in porcine SCNT blastocysts compared to nuclear donor cells and in vitro fertilization (IVF)-derived blastocysts, suggesting that the elongation of telomere lengths observed in cloned piglets could be due to the presence of higher telomerase activity in SCNT blastocysts. In conclusion, gathering from the comparative studies with cattle, we were able to demonstrate that telomere length in cloned piglets was rebuilt or elongated with the use of cultured donor fetal fibroblasts.     

DNA methylation status in somatic and placenta cells of cloned cats

We recently produced 11 cloned kittens by somatic cell nuclear transfer (SCNT) using fibroblasts from a feline fetus (donor A, three kittens), an adult domestic cat (donor B, one kitten), and a deaf adult Turkish Angora cat (donor C, seven kittens). Two kittens were stillborn and three died a month after birth. The donor C-derived kittens did not share their donor's eye color or deafness. To test whether this and the low cloning success rate are due to epigenetic modifications, we compared the methylation of somatic and placental cells from the cloned cats and domestic normal cats by bisulfite mutagenesis sequencing analysis. The DNA methylation of somatic cells from the cloned kittens ranged from 78.0% to 88.9%, and did not differ significantly depending on whether they were stillborn, died early after birth, or were healthy. Donors B and C showed similar levels of methylation (77.0% and 79.1%, respectively), as did somatic cells from normal domestic and Turkish Angora cats (range, 75.7-88.0%). However, donor A showed less methylation (70.6%) than the somatic cells from the kittens derived from it (range, 82.2-88.9%). Moreover, placental cells from three donor C-derived kittens showed significantly higher DNA methylation (range, 76.7-80.5%) than placental cells from normal domestic cats (range, 64.2-74.9%). Thus, methylation of satellite regions in somatic cells may not be responsible for the stillbirth, early death, or different eye and hearing attributes of cloned cats. However, hypermethylation in the placenta of cloned cats may be responsible for low success rates in cloning cats.     

Generation of cloned calves from different types of somatic cells

Remarkable progress has been made in animal cloning research since the first mammal was success-fully cloned[1], and the technique of SCNT is now widely used in biological studies. In theory, successful development of live offspring from SCNT embryos demonstrates that a fully differentiated somatic cell can be reprogrammed and restore its totipotency; in practice, animal cloning can be applied for duplication of elite animals, production of transgenic animals, rescue of endangered species …     

Cloning efficiency following ES cell nuclear transfer is influenced by the methylation state of the donor nucleus altered by mutation of DNA methyltransferase 3a and 3b

The epigenetic state of donor cells plays a vital role in the nuclear reprogramming and chromatin remodeling of cloned embryos. In this study we investigated the effect of DNA methylation state of donor cells on the development of mouse embryos reconstructed with embryonic stem (ES) cell nuclei. Our results confirmed that deletion of the DNA methyltransferase 3a (Dnmt3a) and DNA methyltransferase 3b (Dnmt3b) distinctly decreases the level of DNA methylation in ES cells. In contrast to wild type ES cells (J1), Dnmt3a − / − 3b − / − (DKO) and Dnmt3b − / − (3bKO) donor cells significantly elevated the percentage of embryonic stem cell nuclear transfer (ECNT) morula, blastocysts and postimplantation embryos (P < 0.05). However, the efficiency of establishment of NT-ES cell lines derived from DKO reconstructed blastocysts was not improved, and the expression pattern of OCT4 and CDX2 in cloned blastocysts and postimplantation embryos was not altered either. Our results suggest that the DNA methylation state of the donor nucleus is an important factor in regulation of the donor nuclear reprogramming.