Donor cell differentiation,reprogramming, and cloning efficiency: Elusive or illusive correlation?

Compared to other assisted reproductive technologies, mammalian nuclear transfer (NT) cloning is inefficient in generating viable offspring. It has been postulated that nuclear reprogramming and cloning efficiency can be increased by choosing less differentiated cell types as nuclear donors. This hypothesis is mainly supported by comparative mouse cloning experiments using early blastomeres, embryonic stem (ES) cells, and terminally differentiated somatic donor cells. We have re-evaluated these comparisons, taking into account different NT procedures, the use of donor cells from different genetic backgrounds, sex, cell cycle stages, and the lack of robust statistical significance when post-blastocyst development is compared. We argue that while the reprogrammability of early blastomeres appears to be much higher than that of somatic cells, it has so far not been conclusively determined whether differentiation status affects cloning efficiency within somatic donor cell lineages.     

Universal CG cloning of polymerase chain reaction products

Single-insert cloning of DNA fragments without restriction enzymes has traditionally been achieved using TA cloning, with annealing of a polymerase chain reaction (PCR) fragment containing a single overhanging 3′ A to a plasmid vector containing a 3′ T. In this article, we show that the analogous “CG cloning” is faster and far more efficient, using AhdI to generate a C-vector. For an afternoon ligation, CG cloning achieved double the cloning efficiency and more than 4-fold the number of transformants compared with TA cloning. However, blunt-end ligation was markedly more efficient than both. CG cloning could prove to be extremely useful for single-copy high-throughput cloning.     

Porphyrin rings and phospholipids: stimulators of cloning efficiency in certain species of Tetrahymena.

Species of Tetrahymena, including T. vorax, T. thermophila, T. pyriformis, and T. pigmentosa, were tested for cloning efficiency in proteose peptone and in synthetic nutrient media to which were added hemin, protoporphyrin IX, chlorophyllin, or asolectin, an impure mixture of phospholipids. All species could be cloned with high efficiency in the crude media. In unsupplemented synthetic medium the cloning efficiencies were 0-10%, around 50%, around 50%, and 90-100% for T. thermophila, T. vorax, T. pyriformis, and T. pigmentosa, respectively. The first three were all stimulated to 90-100% by addition of the porphyrin or phospholipid compounds mentioned above. Uroporphyrin III and coproporphyrin I and III had no effect. We suggest that cells unable to form clones suffer from a lack of cellular energy. This situation may be alleviated by our additions, certain porphyrin rings may be built into cytochromes and phospholipids may be used as fuel. Thus, the synthetic media used so far for these ciliates have not been optimal.     

Porphyrin Rings and Phospholipids: Stimulators of Cloning Efficiency in Certain Species of Tetrahymena

ABSTRACT. Species of Tetrahymena , including T. vorax, T. thermophila, T. pyriformis , and T. pigmentosa , were tested for cloning efficiency in proteose peptone and in synthetic nutrient media to which were added hemin, protoporphyrin IX, chlorophyllin, or asolectin, an impure mixture of phospholipids. All species could be cloned with high efficiency in the crude media. In unsupplemented synthetic medium the cloning efficiencies were 0–10%, around 50%, around 50%, and 90–100% for T. thermophila, T. vorax, T. pyriformis , and T. pigmentosa , respectively. The first three were all stimulated to 90–100% by addition of the porphyrin or phospholipid compounds mentioned above. Uroporphyrin III and coproporphyrin I and III had no effect. We suggest that cells unable to form clones suffer from a lack of cellular energy. This situation may be alleviated by our additions: certain porphyrin rings may be built into cytochromes and phospholipids may be used as fuel. Thus, the synthetic media used so far for these ciliates have not been optimal.     

Reprogramming is essential in nuclear transfer

Fertile offspring have been produced by nuclear transfer from adult somatic cells in several mammalian species (Wilmut et al., 1997; Kato et al., 1998; Wakayama et al., 1998; Polejaeva et al., 2000; Chesne et al., 2002; Shin et al., 2002; Zhou et al., 2003). Various possible causes have been suggested for the overall low efficiency (Perry and Wakayama, 2002). Notably, however, it has not yet been clearly demonstrated whether reprogramming after nuclear transfer is necessary for successful cloning. Here we show that reprogramming is essential in nuclear transfer, by comparing the developmental efficiency after the transfer of cumulus cell nuclei with that for zygote nuclei. Nuclear transfers from blastomeres of a series of pre-implantation stages showed further that, as development proceeds, the nuclei progressively lose their potency and become more difficult to reprogram upon their transfer into enucleated MII oocytes. We also found that naturally ovulated oocytes are much better recipients of a nucleus than are superovulated oocytes, which have been used in all the nuclear transfer experiments reported so far. This indicates that cloning efficiency can also be increased to some extent by technical improvements. All these results enable us to distinguish more clearly between the inherent problem of reprogramming and technical problems associated with materials, manipulation, and in vitro culture.     

复杂疾病基因定位策略与肿瘤易感基因鉴定

对于不存在某单一基因位点经典的孟德尔显性或隐性遗传模式的疾病,称为复杂疾病,肿瘤是最常见的类型之一 . 目前,以连锁和相关分析为基础的功能克隆、功能候选克隆、定位克隆、定位候选克隆、系统生物学等复杂疾病易感基因定位策略逐渐发展起来 . 其中,系统生物学策略由于整合了从 DNA 到蛋白质的各个层面的信息,对复杂疾病基因调控网络做出了良好诠释,使其成为最有潜力的方法之一 . 目前,虽然已有近 100 种肿瘤 / 遗传性癌综合症的易感基因被鉴定出来,但未来的复杂疾病易感基因定位工作仍充满了挑战 .     

克隆猪技术及其在转基因猪研究中的应用

哺乳动物核移植技术是一种可以获得基因组遗传信息完全相同的后代的生物技术。猪体细胞核移植技术包括以下几个环节：卵母细胞的体外成熟、供体细胞的分离和处理、体细胞的核转移、重构胚胎的人工激活、胚胎体外培养和胚胎移植。由于该技术在最近几年的迅速发展,很多实验室已通过该技术成功获得了克隆猪后代。核移植克隆猪技术的出现为生产转基因猪提供了一种有效的方法,并且是目前生产基因打靶猪的惟一方法。至今利用克隆猪技术已经成功获得了一系列的转基因猪和基因敲除猪。以核移植技术产生基因修饰猪目前正处于从基础研究走向应用的过渡阶段。尽管猪体细胞核移植克隆的效率（出生克隆猪数占所用卵数的比例）还不高,但是由于通过该技术能够对猪基因组进行特定的修饰,确保生产的克隆动物100％为转基因动物,从而大大提高了转基因猪的制作效率,可以预料猪核移植技术将会对医药业和农业产生重大的影响。     

家畜体细胞克隆中核重编程机理研究进展

体细胞克隆在绵羊、山羊、牛、猪等家畜中获得了成功,但目前的克隆效率非常低。克隆效率低使家畜体细胞克隆技术在畜牧业生产及其他领域的应用受到极大的限制,问题的根源在于对体细胞克隆中核重编程的分子机理缺乏了解。供体细胞核移入去核的卵母细胞后,必须经过后成表观遗传修饰的重编程,从而恢复供体细胞核的全能性,才能保证重构胚的正常发育及个体的正常生长。本文从移植核的重构、DNA甲基化总体改变、组蛋白修饰、X染色体失活、端粒长度和端粒酶活性恢复、印迹基因及其他与发育相关基因的表达及核重编程的影响因素等几个方面探讨了体细胞克隆中的核重编程机理,为克隆效率提高的方法研究提供理论依据。     

Universal TA cloning

TA cloning is one of the simplest and most efficient methods for the cloning of PCR products. The procedure exploits the terminal transferase activity of certain thermophilic DNA polymerases, including Thermus aquaticus (Taq) polymerase. Taq polymerase has non-template dependent activity which preferentially adds a single adenosine to the 3'-ends of a double stranded DNA molecule, and thus most of the molecules PCR amplified by Taq polymerase possess single 3'-A overhangs. The use of a linearized "T-vector" which has single 3'-T overhangs on both ends allows direct, high-efficiency cloning of PCR products, facilitated by complementarity between the PCR product 3'-A overhangs and vector 3'-T overhangs. The TA cloning method can be easily modified so that the same T-vector can be used to clone any double-stranded DNA fragment, including PCR products amplified by any DNA polymerase, as well as all blunt- and sticky-ended DNA species. This technique is especially useful when compatible restriction sites are not available for the subcloning of DNA fragments from one vector to another. Directional cloning is made possible by appropriate hemi-phosphorylation of both the T-vectors and the inserts. With a single T-vector at hand, any DNA fragment can be cloned without compromising the cloning efficiency. The universal TA cloning method is thus both convenient and labor-saving.     

On cloning human beings

The purpose of this paper is to show that arguments for and against cloning fail to make their case because of one or both of the following reasons: 1) they take for granted customary beliefs and assumptions that are far from being unquestionable; 2) they tend to ignore the context in which human cloning is developed. I will analyze some of the assumptions underlying the main arguments that have been offered for and against cloning. Once these assumptions are critically analyzed, arguments both rejecting and supporting human cloning seem to lose weight. I will first briefly present the main arguments that have been proposed against cloning and I will argue that they fail to establish their case. In the next section I will evaluate some of the positive arguments that have been offered supporting such technology. This analysis will show that the case for cloning also fails. Finally, I will maintain that because critics and especially supporters of this technology neglect the context in which human cloning is developed and might be implemented, their arguments are far from compelling.     

Animal cloning applications and issues

Significant progress in the field of biotechnology has allowed for the use of cloning in animals which is being used: to improve genetic makeup, to rescue endangered species, in tissue engineering and to increase farm animal population. Unfortunately, cloning has been met with failure due to a variety of reasons namely early and late abortions, compromised immune systems, circulatory and respiratory problems and a high rate of fetal death. The reasons of these problems are unknown, but may research groups are attempting to understand the underlying molecular and cellular mechanisms involved in cloning efficiency. Atypical epigenetic re-programming appears to be the primary cause of ineffective cloning. Understanding molecular mechanisms involving key regulatory proteins is pivotal in the success of animal cloning. This review shows the current paradigm involving animal cloning efficiency, and also further elucidates applications to improve animal cloning efficiency.     

Human and mouse monoclonal antibodies by repertoire cloning.

Antibody repertoires, the wide range of antibody molecules produced by animals, can now be established in bacteria by cloning and expression of antibody genes. Beginning with immunized animals, antigen can be used to select, from the repertoire, clones which secrete specific monoclonal antibody. In the future, immunization may become unnecessary. The method may provide a general route, which has so far eluded biotechnologists, to human monoclonal antibodies.     

Amphibian and mammal somatic-cell cloning: different species, common results?

Since the production of Dolly the sheep cloning methods for somatic cells have been thoroughly described and are becoming routine. However, the rate at which live clones are produced remains low in all mammalian species tested so far. Remarkably, irrespective of the cloning protocol or the donor-cell type, all clones display common abnormalities, particularly in the placenta. The process is also complicated by early mortality of somatic-cell clones and the founder mammalian clone, Dolly the sheep, died in February 2003 aged six years. Based on published data and on our own experience, our view is that mammalian somatic-cell cloning and the pioneer nuclear-transfer data from amphibians have much in common. We suggest that the only way to improve nuclear reprogramming is to modify the chromatin structure of somatic cells before nuclear transfer, to provide the oocyte with a chromosomal structure that is more compatible with the natural reprogramming machinery of the oocyte.     

Enzyme Free Cloning for high throughput gene cloning and expression

Structural and functional genomics initiatives significantly improved cloning methods over the past few years. Although recombinational cloning is highly efficient, its costs urged us to search for an alternative high throughput (HTP) cloning method. We implemented a modified Enzyme Free Cloning (EFC) procedure, a PCR-only method that eliminates all variables other than PCR efficiency by circumventing enzymatic treatments. We compared the cloning efficiency of EFC with that of Ligation Independent Cloning (LIC). Both methods are well suited for HTP cloning, but EFC yields three times more transformants and a cloning efficiency of 91%, comparable with recombinational cloning methods and significantly better than LIC (79%). EFC requires only nanogram amounts of both vector and insert, does not require highly competent cells and is, in contrast to LIC, largely insensitive to variations in PCR product concentration. Automated protein expression screening of expression strains directly transformed with EFC reactions showed, that the traditional preceding step via a cloning strain can be circumvented. EFC proves an efficient and robust HTP cloning method, that is compatible with existing Ligation Independent Cloning vectors, and highly suitable for automation.     

Coordination between donor cell type and cell cycle stage improves nuclear cloning efficiency in cattle

Several studies have shown that both quiescent and proliferating somatic donor cells can be fully reprogrammed after nuclear transfer (NT) and result in viable offspring. So far, however, no comparative study has conclusively demonstrated the relative importance of donor cell cycle stage on nuclear cloning efficiency. Here, we compare two different types of bovine fetal fibroblasts (BFFs) that were synchronized in G(0), G(1), and different phases within G(1). We show that for non-transgenic (non-TG) fibroblasts, serum starvation into G(0) results in a significantly higher percentage of viable calves at term than synchronization in early G(1) or late G(1). For transgenic fibroblasts, however, cells selected in G(1) show significantly higher development to calves at term and higher post-natal survival to weaning than cells in G(0). This suggests that it may be necessary to coordinate donor cell type and cell cycle stage to maximize overall cloning efficiency.     

Zinc-metalloproteases in insects: ACE and ECE

Research on the angiotensin-converting enzyme (ACE) in insects has substantially advanced during the recent decade. The cloning of this enzyme in many insect species, the determination of the 3D-structure and several molecular and physiological studies have contributed to the characterization of insect ACE as we know it today: a functional enzyme with a putative role in reproduction, development and defense. The discovery of the endothelin-converting enzyme in insects occurred more recently and cloning of the corresponding cDNA has been carried out in only one insect species so far. However, activity studies and analysis of insect genomes indicate that this enzyme is also widely distributed among insect species. Making hypotheses about its putative function would be preliminary, but its wide tissue distribution suggests a major and diverse biological role.     

Introduction of chloramphenicol resistance into the modified mouse mitochondrial genome: cloning of unstable sequences by passage through yeast

Despite increasing awareness of the importance of the mitochondrial genome in human pathology, very few attempts have been made so far toward genetic engineering of mitochondrial DNA (mtDNA). One of the reasons for this slow progress is the difficulty of cloning mtDNA in Escherichia coli, a trait in common with repetitive or palindromic sequences, and some viral sequences. We have previously made a construct containing the entire mouse mitochondrial genome and a cDNA sequence coding for human ornithine transcarbamylase in a yeast/bacterial shuttle vector, which can be stably maintained in E. coli. We wished to modify this vector for mitochondrial gene therapy by the addition of mitochondrial chloramphenicol resistance, conferred by a point mutation in the 16S rRNA gene. Attempts to modify this construct by a straightforward cloning approach in E. coli proved unsuccessful. Two successful strategies for modification of large unstable constructs in both E. coli and the yeast Saccharomyces cerevisiae are compared here.     

Cloning of non-human primates: the road "less traveled by"

Early studies on cloning of non-human primates by nuclear transfer utilized embryonic blastomeres from preimplantation embryos which resulted in the reproducible birth of live offspring. Soon after, the focus shifted to employing somatic cells as a source of donor nuclei (somatic cell nuclear transfer, SCNT). However, initial efforts were plagued with inefficient nuclear reprogramming and poor embryonic development when standard SCNT methods were utilized. Implementation of several key SCNT modifications was critical to overcome these problems. In particular, a non-invasive method of visualizing the metaphase chromosomes during enucleation was developed to preserve the reprogramming capacity of monkey oocytes. These modifications dramatically improved the efficiency of SCNT, yielding high blastocyst development in vitro. To date, SCNT has been successfully used to derive pluripotent embryonic stem cells (ESCs) from adult monkey skin fibroblasts. These remarkable advances have the potential for development of human autologous ESCs and cures for many human diseases. Reproductive cloning of nonhuman primates by SCNT has not been achieved yet. We have been able to establish several pregnancies with SCNT embryos which, so far, did not progress to term. In this review, we summarize the approaches, obstacles and accomplishments of SCNT in a non-human primate model.