In the fast lane: large-scale bacterial genome engineering

The last few years have witnessed rapid progress in bacterial genome engineering. The long-established, standard ways of DNA synthesis, modification, transfer into living cells, and incorporation into genomes have given way to more effective, large-scale, robust genome modification protocols. Expansion of these engineering capabilities is due to several factors. Key advances include: (i) progress in oligonucleotide synthesis and in vitro and in vivo assembly methods, (ii) optimization of recombineering techniques, (iii) introduction of parallel, large-scale, combinatorial, and automated genome modification procedures, and (iv) rapid identification of the modifications by barcode-based analysis and sequencing. Combination of the brute force of these techniques with sophisticated bioinformatic design and modeling opens up new avenues for the analysis of gene functions and cellular network interactions, but also in engineering more effective producer strains. This review presents a summary of recent technological advances in bacterial genome engineering.     

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.     

合成芳香族化合物的酵母底盘改造策略*

芳香族化合物种类丰富,在多个行业具有广泛的用途,需求量大。通过构建微生物细胞工厂合成芳香族化合物具有独特的优势和工业化应用前景,其中酵母底盘因其清晰的遗传背景、完善的基因操作工具以及成熟的工业发酵体系等优势,常被用于构建细胞工厂。目前改造酵母底盘生产芳香族化合物的研究取得了一系列进展,并针对关键问题提出了一些可行的解决策略。针对酵母合成芳香族化合物的策略与挑战,从芳香族化合物合成路径改造、多样化碳源利用及转运系统改造、基因组多靶点改造、特殊酵母底盘及混菌系统构建、合成生物学高通量技术的应用这五个方面进行系统地梳理和阐述,为生产芳香族化合物的酵母底盘构建与改造提供思路。     

High‐efficiency gene targeting in hexaploid wheat using DNA replicons and CRISPR/Cas9

The ability to edit plant genomes through gene targeting (GT) requires efficient methods to deliver both sequence‐specific nucleases (SSNs) and repair templates to plant cells. This is typically achieved using Agrobacterium T‐DNA, biolistics or by stably integrating nuclease‐encoding cassettes and repair templates into the plant genome. In dicotyledonous plants, such as Nicotinana tabacum (tobacco) and Solanum lycopersicum (tomato), greater than 10‐fold enhancements in GT frequencies have been achieved using DNA virus‐based replicons. These replicons transiently amplify to high copy numbers in plant cells to deliver abundant SSNs and repair templates to achieve targeted gene modification. In the present work, we developed a replicon‐based system for genome engineering of cereal crops using a deconstructed version of the wheat dwarf virus (WDV). In wheat cells, the replicons achieve a 110‐fold increase in expression of a reporter gene relative to non‐replicating controls. Furthermore, replicons carrying CRISPR/Cas9 nucleases and repair templates achieved GT at an endogenous ubiquitin locus at frequencies 12‐fold greater than non‐viral delivery methods. The use of a strong promoter to express Cas9 was critical to attain these high GT frequencies. We also demonstrate gene‐targeted integration by homologous recombination (HR) in all three of the homoeoalleles (A, B and D) of the hexaploid wheat genome, and we show that with the WDV replicons, multiplexed GT within the same wheat cell can be achieved at frequencies of ~1%. In conclusion, high frequencies of GT using WDV‐based DNA replicons will make it possible to edit complex cereal genomes without the need to integrate GT reagents into the genome.     

Genome-scale genetic engineering in Escherichia coli

Genome engineering has been developed to create useful strains for biological studies and industrial uses. However, a continuous challenge remained in the field: technical limitations in high-throughput screening and precise manipulation of strains. Today, technical improvements have made genome engineering more rapid and efficient. This review introduces recent advances in genome engineering technologies applied to Escherichia coli as well as multiplex automated genome engineering (MAGE), a recent technique proposed as a powerful toolkit due to its straightforward process, rapid experimental procedures, and highly efficient properties.     

Dynamic metabolic engineering: New strategies for developing responsive cell factories

Metabolic engineering strategies have enabled improvements in yield and titer for a variety of valuable small molecules produced naturally in microorganisms, as well as those produced via heterologous pathways. Typically, the approaches have been focused on up‐ and downregulation of genes to redistribute steady‐state pathway fluxes, but more recently a number of groups have developed strategies for dynamic regulation, which allows rebalancing of fluxes according to changing conditions in the cell or the fermentation medium. This review highlights some of the recently published work related to dynamic metabolic engineering strategies and explores how advances in high‐throughput screening and synthetic biology can support development of new dynamic systems. Dynamic gene expression profiles allow trade‐offs between growth and production to be better managed and can help avoid build‐up of undesired intermediates. The implementation is more complex relative to static control, but advances in screening techniques and DNA synthesis will continue to drive innovation in this field.     

植物基因替换编辑技术研究进展

基因替换编辑是通过核酸酶介导的对目标基因进行定点敲入或替换的编辑技术,可以实现目的基因的定向修饰。本文从基因替换编辑技术的原理、实现方式与影响因素、应用及其前景等进行了总结与讨论,以期为通过定点基因替换或敲入技术开展高等植物基因功能鉴定与遗传改良研究提供参考。     

Gene stacking by recombinases

Efficient methods of stacking genes into plant genomes are needed to expedite transfer of multigenic traits to crop varieties of diverse ecosystems. Over two decades of research has identified several DNA recombinases that carryout efficient cis and trans recombination between the recombination sites artificially introduced into the plant chromosome. The specificity and efficiency of recombinases make them extremely attractive for genome engineering. In plant biotechnology, recombinases have mostly been used for removing selectable marker genes and have rarely been extended to more complex applications. The reversibility of recombination, a property of the tyrosine family of recombinases, does not lend itself to gene stacking approaches that involve rounds of transformation for integrating genes into the engineered sites. However, recent developments in the field of recombinases have overcome these challenges and paved the way for gene stacking. Some of the key advancements include the application of unidirectional recombination systems, modification of recombination sites and transgene site modifications to allow repeated site‐specific integrations into the selected site. Gene stacking is relevant to agriculturally important crops, many of which are difficult to transform; therefore, development of high‐efficiency gene stacking systems will be important for its application on agronomically important crops, and their elite varieties. Recombinases, by virtue of their specificity and efficiency in plant cells, emerge as powerful tools for a variety of applications including gene stacking.     

Glycosyltransferases:key players involved in the modification of plant secondary metabolites

Glycosyltransferases are members of the multigene superfamily in plants that can transfer single or multiple activated sugars to a range of plant molecules,resulting in the glycosylation of plant compounds.Although the activities of many glycosyltransferases and their products have been recognized for a long time,only in recent years were some glycosyltransferase genes identified and a few functionally characterized in detail.Glycosylation is thought to be one of the most important modification reactions towards plant secondary metabolites,and plays a key role in maintaining cell homeostasis,thus likely participating in the regulation of plant growth,development and in defense responses to stress environments.With advances in plant genome projects and the development of novel technologies in analyzing gene function,significant progress could be made in gaining new insights into the properties and precise biological roles of plant secondary product glycosyltransferases,and the new knowledge will have extensive application prospects in the catalytic synthesis of glycoconjugates and metabolic engineering of crops.In this review,we summarize the current research,highlighting the possible biological roles,of plant secondary metabolite glycosyltransferases and discuss their potential applications as well as aspects to be further studied in the near future.     

Glycosyltransferases: key players involved in the modification of plant secondary metabolites

Glycosyltransferases are members of the multigene superfamily in plants that can transfer single or multiple activated sugars to a range of plant molecules, resulting in the glycosylation of plant compounds. Although the activities of many glycosyltransferases and their products have been recognized for a long time, only in recent years were some glycosyltransferase genes identified and a few functionally characterized in detail. Glycosylation is thought to be one of the most important modification reactions towards plant secondary metabolites, and plays a key role in maintaining cell homeostasis, thus likely participating in the regulation of plant growth, development and in defense responses to stress environments. With advances in plant genome projects and the development of novel technologies in analyzing gene function, significant progress could be made in gaining new insights into the properties and precise biological roles of plant secondary product glycosyltransferases, and the new knowledge will have extensive application prospects in the catalytic synthesis of glycoconjugates and metabolic engineering of crops. In this review, we summarize the current research, highlighting the possible biological roles, of plant secondary metabolite glycosyltransferases and discuss their potential applications as well as aspects to be further studied in the near future.     

Developing a Cas9‐based tool to engineer native plasmids in Synechocystis sp. PCC 6803

The oxygenic photosynthetic bacterium Synechocystis sp. PCC 6803 (S6803) is a model cyanobacterium widely used for fundamental research and biotechnology applications. Due to its polyploidy, existing methods for genome engineering of S6803 require multiple rounds of selection to modify all genome copies, which is time‐consuming and inefficient. In this study, we engineered the Cas9 tool for one‐step, segregation‐free genome engineering. We further used our Cas9 tool to delete three of seven S6803 native plasmids. Our results show that all three small‐size native plasmids, but not the large‐size native plasmids, can be deleted with this tool. To further facilitate heterologous gene expression in S6803, a shuttle vector based on the native plasmid pCC5.2 was created. The shuttle vector can be introduced into Cas9‐containing S6803 in one step without requiring segregation and can be stably maintained without antibiotic pressure for at least 30 days. Moreover, genes encoded on the shuttle vector remain functional after 30 days of continuous cultivation without selective pressure. Thus, this study provides a set of new tools for rapid modification of the S6803 genome and for stable expression of heterologous genes, potentially facilitating both fundamental research and biotechnology applications using S6803.     

烟草花叶病毒复制酶介导抗性的研究进展

在抗病毒植物基因工程中,利用病毒的复制酶基因是一种很有前途的方法。本对烟草花叶病毒（TMV）的基因组结构及其编码的蛋白的功能作了简介,同时较详细地阐述了由TMV复制本科的通读部分、全长复制酶以及突变或缺失的复制酶介导的对病毒抗性的研究进展。     

Strain Engineering by Genome Mass Transfer: Efficient Chromosomal Trait Transfer Method Utilizing Donor Genomic DNA and Recipient Recombineering Hosts

Strain engineering, like cloning, is a fundamental technology used to confer new traits onto existing strains. While effective methods for trait development through gene modification within strains have been developed, methods for trait transfer between Escherichia coli strains to create complex strains are needed. We report herein the development of genome mass transfer (GMT), a broadly applicable new strain engineering methodology enabling rapid trait transfer from a donor strain into a recombineering gene-expressing recipient strain. GMT utilizes electroporation of donor chromosomal DNA into a recombineering recipient cell for precise trait transfer. GMT transfer of traits between E. coli strains can be used to rapidly assemble new strains incorporating combinations of marked gene knockouts, for example, utilizing the existing E. coli K-12 Keio gene knockout collection as source target genes. Optional use of random primed isothermal amplified DNA eliminates the need for initial DNA purification, affording high throughput application. This allows unprecedented simplicity and speed for rational design engineering of complex phenotypes in industrial strains.     

Plant artificial chromosome technology and its potential application in genetic engineering

Genetic engineering with just a few genes has changed agriculture in the last 20 years. The most frequently used transgenes are the herbicide resistance genes for efficient weed control and the Bt toxin genes for insect resistance. The adoption of the first‐generation genetically engineered crops has been very successful in improving farming practices, reducing the application of pesticides that are harmful to both human health and the environment, and producing more profit for farmers. However, there is more potential for genetic engineering to be realized by technical advances. The recent development of plant artificial chromosome technology provides a super vector platform, which allows the management of a large number of genes for the next generation of genetic engineering. With the development of other tools such as gene assembly, genome editing, gene targeting and chromosome delivery systems, it should become possible to engineer crops with multiple genes to produce more agricultural products with less input of natural resources to meet future demands.     

Precision genetic modifications: a new era in molecular biology and crop improvement

Recently, the use of programmable DNA-binding proteins such as ZFP/ZFNs, TALE/TALENs and CRISPR/Cas has produced unprecedented advances in gene targeting and genome editing in prokaryotes and eukaryotes. These advances allow researchers to specifically alter genes, reprogram epigenetic marks, generate site-specific deletions and potentially cure diseases. Unlike previous methods, these precision genetic modification techniques (PGMs) are specific, efficient, easy to use and economical. Here we discuss the capabilities and pitfalls of PGMs and highlight the recent, exciting applications of PGMs in molecular biology and crop genetic engineering. Further improvement of the efficiency and precision of PGM techniques will enable researchers to precisely alter gene expression and biological/chemical pathways, probe gene function, modify epigenetic marks and improve crops by increasing yield, quality and tolerance to limiting biotic and abiotic stress conditions.