Advances in homology directed genetic engineering of human pluripotent and adult stem cells

The ability to introduce precise genomic modifications in human cells has profound implications for both basic and applied research in stem cells, ranging from identification of genes regulating stem cell self-renewal and multilineage differentiation to therapeutic gene correction and creation of in vitro models of human diseases. However, the overall efficiency of this process is challenged by several factors including inefficient gene delivery into stem cells and low rates of homology directed site-specific targeting. Recent studies report the development of novel techniques to improve gene targeting efficiencies in human stem cells; these methods include molecular engineering of viral vectors to efficiently deliver episomal genetic sequences that can participate in homology directed targeting, as well as the design of synthetic proteins that can introduce double-stranded breaks in DNA to initiate such recombination events. This review focuses on the potential of these new technologies to precisely alter the human stem cell genome and also highlights the possibilities offered by the combination of these complementary strategies.     

CRISPR/Cas9 and Genome Editing in Drosophila

Recent advances in our ability to design DNA binding factors with specificity for desired sequences have resulted in a revolution in genetic engineering, enabling directed changes to the genome to be made relatively easily. Traditional techniques for generating genetic mutations in most organisms have relied on selection from large pools of randomly induced mutations for those of particular interest, or time-consuming gene targeting by homologous recombination. Drosophila melanogaster has always been at the forefront of genetic analysis, and application of these new genome editing techniques to this organism will revolutionise our approach to performing analysis of gene function in the future. We discuss the recent techniques that apply the CRISPR/Cas9 system to Drosophila, highlight potential uses for this technology and speculate upon the future of genome engineering in this model organism.     

Targeted Genome Editing by Recombinant Adeno-Associated Virus （rAAV） Vectors for Generating Genetically Modified Pigs

Recombinant adeno-associated virus(rAAV) vectors have been extensively used for experimental gene therapy of inherited human diseases.Several advantages,such as simple vector construction,high targeting frequency by homologous recombination,and applicability to many cell types,make rAAV an attractive approach for targeted genome editing.Combined with cloning by somatic cell nuclear transfer(SCNT),this technology has recently been successfully adapted to generate gene-targeted pigs as models for cystic fibrosis, hereditary tyrosinemia type 1,and breast cancer.This review summarizes the development of rAAV for targeted genome editing in mammalian cells and provides strategies for enhancing the rAAV-mediated targeting frequency by homologous recombination.We discuss current development and application of the rAAV vectors for targeted genome editing in porcine primary fibroblasts,which are subsequently used as donor cells for SCNT to generate cloned genetically designed pigs and provide positive perspectives for the generation of gene-targeted pigs with rAAV in the future.     

Enabling technology and core theory of synthetic biology

Synthetic biology provides a new paradigm for life science research(“build to learn”) and opens the future journey of biotechnology(“build to use”). Here, we discuss advances of various principles and technologies in the mainstream of the enabling technology of synthetic biology, including synthesis and assembly of a genome, DNA storage, gene editing, molecular evolution and de novo design of function proteins, cell and gene circuit engineering, cell-free synthetic biology, artificial intelligen...     

The Role of Chromatin Modifications in Progression through Mouse Meiotic Prophase

Meiosis is a key event in gametogenesis that generates new combinations of genetic information and is required to reduce the chro- mosome content of the gametes. Meiotic chromosomes undergo a number of specialised events during prophase to allow meiotic recombination, homologous chromosome synapsis and reductional chromosome segregation to occur. In mammalian cells, DNA phys- ically associates with histones to form chromatin, which can be modified by methylation, phosphorylation, ubiquitination and acetylation to help regulate higher order chromatin structure, gene expression, and chromosome organisation. Recent studies have identified some of the enzymes responsible for generating chromatin modifications in meiotic mammalian cells, and shown that these chromatin modifying enzymes are required for key meiosis-specific events that occur during meiotic prophase. This review will discuss the role of chromatin modifications in meiotic recombination, homologous chromosome synapsis and regulation of meiotic gene expression in mammals.     

苔藓植物小立碗藓，功能基因组学研究新的模式系统

苔藓植物具有相对简单的发育模式,单倍体的配子体在其生活史中占主导地位,作为研究植物生物学过程的模式系统具有诸多的优越性。苔藓植物小立碗藓能够高效地通过同源重组的方式将外源核酸整合到其核DNA,这就使得基因打靶在此物种中就像在小鼠胚胎干细胞和酵母中一样成为一个非常便利的技术。另外由于小立碗藓与高等植物在生物特征上有很大相似之处加之其有其他诸多优越性,它有望成为一个诱人的植物生物学和功能基因组学研究的模式系统。Abstract：The potential of moss as a model system to study plant biological process is associated with their relatively simple developmental pattern and the dominance of the haploid gametophyte in the life cycle. The moss Physcomitrella patens exhibits a very high rate of homologous recombination in its nuclear DNA, making gene targeting approaches in this plant as convenient as in yeast or in ES cells of mice. Sharing many biological features with higher plants and having many other advantages, the moss Physcomitrella patens will be an attractive model system for plant biology and functional genome analysis.     

植物基因打靶效率的研究进展

基因打靶技术是将外源DNA定向整合入基因组中对特定基因进行精确修饰,从而改变生物遗传性状的技术。它在特定基因功能研究、遗传育种和生理机制的理解方面有着重要意义,但植物中较低的基因打靶效率制约着它的进一步推广和应用。本文着重从载体构建、筛选策略、受体细胞状态等方面对打靶效率的提高进行分析,并介绍同源重组酶系、锌指核酶和寡核苷酸技术在基因打靶中的应用。     

植物基因打靶研究现状

基因打靶是八十年代后期发展起来的一门新兴的遗传工程技术,基因打靶技术在探索生物的基因功能,消除转基因的沉默,提高转基因的稳定性和表达效率以及基因治疗等方面均取得了进展。基因打靶技术的应用前景广阔,它的产生是遗传工程领域的一次革命。目前,基因打靶在植物上的应用研究才刚起步。本文针对基因打靶在植物上的研究现状作一综述。     

Pooling and PCR as a method to combat low frequency gene targeting in mouse embryonic stem cells

The introduction of germ line modifications by gene targeting in mouse embryonic stem (ES) cells has proven a fundamental technology to relate genes to mammalian biology. Critical aspects required for successful gene targeting have traditionally been experimental enhancements that increase the frequency or detection of homologous recombination within ES cells; however, the utilization of such methods may still result in the failed isolation of a positively targeted ES cell clone. In this study, we discuss the current enhancement methods and describe an ES cell pooling strategy that maximizes the ability to detect properly targeted ES cells regardless of an inherent low targeting efficiency. The sensitivity required to detect correctly targeted events out of a pool of ES cell clones is provided by polymerase chain reaction (PCR), and only those pools containing positives need to be expanded and screened to find individually targeted clones. This method made it possible to identify targeted clones from a screen of approximately 2,300 ES cell colonies by performing only 123 PCR reactions. This technically streamlined approach bypasses the need to troubleshoot and re-engineer an existing targeting construct that is functionally suitable despite its low targeting frequency.     

体细胞基因打靶制备动物乳腺生物反应器的策略与应用

在转基因动物研究中,由于基因表达调控元件的人工拼接和外源基因在动物基因组中随机整合所带来的“位置效应”,致使转基因动物外源基因的表达水平不高并且差异较大。为此,利用定位整合优势,对以基因同源重组为基础的基因打靶技术进行了大量研究。介绍了就利用体细胞基因打靶和核移植技术制备动物乳腺生物反应器的策略和应用情况做一综述,并对提高基因打靶效率的各种策略,打靶细胞的选择,转基因细胞核移植的低融合事件以及基因打靶制备乳腺生物反应器的优越性进行分析。     

基因打靶及其应用

用活细胞染色体DNA可与外源性DNA同源序列发生同源重组的性质,达到定点修饰改造染色体某基因的目的,此法称基因打靶．基因的同源重组是较普遍的生物现象,其分子机理尚未阐明,但活细胞内确有一酶系可使DNA的同源序列在细胞内发生重组,这一事实已无可争辨．此事实为基因打靶的理论基础．基因打靶技术操作的关键是建立一含筛选基因的重组载体,并有效地把它转入细胞核内．基因打靶命中的细胞可稳定遗传．基因打靶在改造生物品种,一些复杂生命现象（如发育的分子机制等）及临床理论研究均有广阔的前景．     

Baculovirus display strategies: Emerging tools for eukaryotic libraries and gene delivery.

Recombinant baculoviruses have been extensively used as vectors for abundant expression of a large variety of foreign proteins in insect cell cultures. The appeal of the system lies essentially in easy cloning techniques and virus propagation combined with the eukaryotic post-translational modification machinery of the insect cell. Recently, a novel molecular biology tool was established by the development of baculovirus surface display, using different strategies for presentation of foreign peptides and proteins on the surface of budded virions. This eukaryotic display system enables presentation of large complex proteins on the surface of baculovirus particles and has thereby become a versatile system in molecular biology. Surface display strategies play an important role, as they may be used to enhance the efficiency and specificity of viral binding and entry to mammalian cells. In addition, baculovirus surface display vectors have been engineered to contain mammalian promoter elements designed for gene delivery both in vitro and in vivo. Moreover, baculovirus capsid display has recently been developed; this holds promise for intracellular targeting of the viral capsid and subsequent cytosolic delivery of desired protein moieties. Finally, the viruses can accommodate large insertions of foreign DNA and replicate only in insect cells. Together, these are attributes that are very likely to make them important tools in functional genomics and proteomics.     

Improved method for the PCR-based gene disruption in Saccharomyces cerevisiae

The PCR-based gene disruption strategy originally devised by Baudin et al. is widely used for gene targeting in Saccharomyces cerevisiae. An advantage of this strategy is its simplicity in making targeting constructs. The efficiencies of the targeted disruption are highly variable from locus to locus, however, and often very low. In this report, a method for improving the gene deletion efficiency is described.     

基因打靶技术及其应用前景

基因打靶是近年来发展起来的对细胞基因组中的某一基因进行定点操作的生物技术。综述了基因打靶的筛选系统,影响基因打靶的几个主要因素及其解决方法,总结了基因打靶在各个学科领域中的应用。     

植物基因打靶技术

基因打靶是反向遗传学的基础工具,它通过同源重组置换染色体内的基因用于复杂基因组的基因功能分析。但是,在植物中,外源DNA的插入主要是非序列依赖的非同源末端连接方式,基因打靶频率很低,只有10-5～10-4的水平。综述了近年来为了提高植物基因打靶频率,研究人员的工作和最新进展 。     

综述:基于人多潜能干细胞的人类疾病研究与治疗

人多潜能干细胞(hPSC)包括人胚胎干细胞(hESC)和诱导性多潜能干细胞(hiPSC),理论上具有分化成为人类所有细胞类型的能力.基于hPSC的基因打靶技术,不但可以纠正人基因组中的遗传突变用于细胞治疗,还可以通过反向遗传学的方式向hPSC引入疾病特异的突变.将携带人类疾病遗传基因的hPSC分化为特定的细胞类型,在理论上可以在体外模拟人类疾病的发生,研究人类疾病发生的机理,并建立体外筛选平台寻找治疗性药物.基因编辑和干细胞技术的结合将为人类疾病的机制研究和再生医学治疗带来革命性的突破.