Genetic and Genomic Toolbox of the Chordate Ciona intestinalis

The experimental malleability and unique phylogenetic position of the sea squirt Ciona intestinalis as part of the sister group to the vertebrates have helped establish these marine chordates as model organisms for the study of developmental genetics and evolution. Here we summarize the tools, techniques, and resources available to the Ciona geneticist, citing examples of studies that employed such strategies in the elucidation of gene function in Ciona. Genetic screens, germline transgenesis, electroporation of plasmid DNA, and microinjection of morpholinos are all routinely employed, and in the near future we expect these to be complemented by targeted mutagenesis, homologous recombination, and RNAi. The genomic resources available will continue to support the design and interpretation of genetic experiments and allow for increasingly sophisticated approaches on a high-throughput, whole-genome scale.     

Characterization of transgenic mice expressing cancer-associated variants of human NOTCH1

The Notch1 receptor plays a critical role in cell fate decisions during development. Activation of Notch signaling has been implicated in several types of cancer, particularly T-cell acute lymphoblastic leukemia (T-ALL). Consequently, several transgenic mouse strains have been made to study the role of Notch1 in T-ALL. However, the existing Notch1 transgenic lines mimic a translocation event found in only ～1% of T-ALL cases. Here we describe three novel NOTCH1 transgenic mouse strains that have Cre-inducible expression of the entire human NOTCH1 locus, each possessing a common mutation found in T-ALL. Unlike existing Notch1 transgenic strains, these NOTCH1 transgenic strains express full-length receptors from an endogenous human promoter that should be susceptible to a number of Notch antagonists that have recently been developed. These strains will allow researchers to modulate Notch signaling to study both normal development and cancer biology.     

Highly-efficient, fluorescent, locus directed cre and FlpO deleter mice on a pure C57BL/6N genetic background

To facilitate the use of the new mutant resource developed in the mouse, we have generated Cre and FlpO deleter mice on a pure inbred C57BL/6N background. The new transgenic constructs were designed to drive either the Cre or FlpO recombinase, fused to a specific fluorescent marker, respectively the eGFP or the eYFP, and were inserted by homologous recombination in the neutral Rosa26 locus. They allow a rapid, cost-effective, and efficient identification of the carrier individuals through the coexpression of the fluorescent marker. The recombination efficiency of the two deleter lines, Gt(ROSA)26S or < tm1(ACTB-cre,-EGFP)Ics> and Gt(ROSA) 26S or < tm2(CAG-flpo, EYFP)Ics>, was carefully evaluated using five loxP-flanked or four FRT-flanked alleles located at different positions in the mouse genome. For each tested locus, we observed a 100% excision rate. The transgenic mice are easily distinguishable from wild type animals by their bright fluorescence that remains easily detectable until 10 days after birth. In the adult, fluorescence can still be detected in the unpigmented paws. Furthermore, they both display accumulation of the specific recombinase during oogenesis. These fluorescent 'Cre- and Flp- deleter' transgenic lines are valuable tools for the scientific community by their high and stable recombination efficiency, the simplicity of genotype identification and the maintenance of a pure genetic background when used to remove specific selection cassette or to induce complete loss-of-function allele.     

In vitro Development of Murine Embryos Using Different Types of Microinjections

We studied the effects of different types of microinjections, such as the mechanical damage to cytoplasmic and nuclear membranes of the zygote and the injection of various gene-engineering constructs or buffer solutions into the cytoplasm or the pronucleus, on the preimplantation of murine embryos (CBA × C57BL)F₁. The survival rate of the embryos was estimated by their capacity to develop in vitro to the blastocyst or hatched blastocyst stages. Puncture of the cytoplasm using a microneedle and injection of buff or foreign DNA did not affect the zygotes capacity for further in vitro development. But, the puncture of the pronucleus and microinjection of gene-engineering constructs or buffer into it reliably decreased the survival rate of embryos, as compared to the control. The differences were found in the capacity of murine zygotes for in vitro development after injection with gene-engineering constructs.     

转基因动物在输血医学中的应用

转基因动物技术是在动物整体水平研究和表达目的基因的生物技术,其基本特点是：分子及细胞水平操作,组织及整体水平表达,是常规分子生物学理论和技术的拓展和延伸,也是现代生物高技术研究和开发的热点之一。本简述了转基因动物在输血医学领域的应用及其发展前景,包括利用转基因动物生物反应器制备人血浆蛋白和人血红蛋白、建立血传播病毒的感染模型和血液相关遗传模型以及转基因动物与输血医学的基础研究等。     

Improvement of Transfection Efficiency in Cultured Chicken Primordial Germ Cells by Percoll Density Gradient Centrifugation

Chicken primordial germ cells (PGCs) differentiate into germ cells in gonads. Because PGCs can be cloned and cultured maintaining germline competency, they are a good means of modifing the chicken genome, but the efficiency of plasmid transfection into PGCs is very low. In this study, I attempted to improve the efficiency of PGC transfection. Cultured PGCs were purified by Percoll density gradient centrifugation, and were then transfected with plasmid DNA. For transient transfection, the transfection efficiency increased more than 7-fold by the Percoll method. The efficiency of stable transfection of PGCs also increased significantly. The stable transfectants that were isolated by this method accumulated in the developing gonads after microinjection into bloodstream of chick embryos, indicating that gene transfection by Percoll purification did not alter the function of PGCs in vivo.     

Challenges facing European agriculture and possible biotechnological solutions

Agriculture faces many challenges to maximize yields while it is required to operate in an environmentally sustainable manner. In the present study, we analyze the major agricultural challenges identified by European farmers (primarily related to biotic stresses) in 13 countries, namely Belgium, Bulgaria, the Czech Republic, France, Germany, Hungary, Italy, Portugal, Romania, Spain, Sweden, UK and Turkey, for nine major crops (barley, beet, grapevine, maize, oilseed rape, olive, potato, sunflower and wheat). Most biotic stresses (BSs) are related to fungi or insects, but viral diseases, bacterial diseases and even parasitic plants have an important impact on yield and harvest quality. We examine how these challenges have been addressed by public and private research sectors, using either conventional breeding, marker-assisted selection, transgenesis, cisgenesis, RNAi technology or mutagenesis. Both national surveys and scientific literature analysis followed by text mining were employed to evaluate genetic engineering (GE) and non-GE approaches. This is the first report of text mining of the scientific literature on plant breeding and agricultural biotechnology research. For the nine major crops in Europe, 128 BS challenges were identified with 40% of these addressed neither in the scientific literature nor in recent European public research programs. We found evidence that the private sector was addressing only a few of these “neglected” challenges. Consequently, there are considerable gaps between farmer’s needs and current breeding and biotechnology research. We also provide evidence that the current political situation in certain European countries is an impediment to GE research in order to address these agricultural challenges in the future. This study should also contribute to the decision-making process on future pertinent international consortia to fill the identified research gaps.