Methods to produce marker-free transgenic plants

Selectable marker genes (SMGs) have been extraordinarily useful in enabling plant transformation because of the low efficiency of transgene integration. The most used SMGs encode proteins resistant to antibiotics or herbicides and use negative selection, i.e., by killing nontransgenic tissue. However, there are perceived risks in wide-scale deployment of SMG-transgenic plants, and therefore research has recently been performed to develop marker-free systems. In this review, transformation using markers not based on antibiotic or herbicide resistance genes, as well as different systems of marker gene deletion, are discussed.     

Selectable marker genes from plants: reliability and potential

Selectable marker genes (SMGs) are still useful to efficiently obtain transgenic plants, although marker-free techniques are available, but with limitations. The presence of SMGs, especially bacterial antibiotic resistance genes, in transgenic crops is criticized. Fortunately, several genes isolated from plants are available that can serve as SMGs. Here, I review the plant genes reported to have been used as SMGs. Some are wild-type genes that, when overexpressed, confer a selective advantage during in vitro plant regeneration, whereas some are mutated genes encoding enzymes resistant to inhibitory chemicals. Most of the genes have not yet been tested in a significant number of species. The effect of SMGs expression on the phenotype has often been superficially examined and should be better characterized. The sequence conservation of some SMGs could allow derivation of a SMGs from any plant species, if an intragenic or cisgenic approach to genetic engineering is preferred. I conclude that several promising SMGs have been isolated from plants, allowing avoidance of bacterial genes for transformation, transgene stacking, and intragenic or cisgenic engineering approaches. Nonetheless, further testing in more plant species would be useful to fully assess phenotypic neutrality, efficiency, and versatility. Patent rights restrict the immediate use of most plant SMGs for commercial applications, but freely available marker systems do exist.     

Non-antibiotic,efficient selection for alfalfa genetic engineering

A selectable marker gene (SMG), usually conferring resistance to an antibiotic or herbicide, is generally introduced into the plant cells with the gene(s) for the trait of interest to allow only the cells that have integrated and express the foreign sequences to regenerate into a plant. The availability of several SMGs for each plant species is useful for both basic and applied research to combine several genes of interest in the same plant. A selection system based on gabaculine (3-amino-2,3-dihydrobenzoic acid) as the selective substance and the bacterial hemL gene [encoding a mutant for of the enzyme glutamate 1-semialdehyde aminotransferase (GSA-AT)] as the SMG was previously used for genetic transformation of tobacco. The hemL gene is a good candidate for a safe SMG, because GSA-AT is present in all plants and is likely involved in one metabolic step only, so that unintended effects of its overexpression in plants are not probable. In this work, we have compared this new selection system with the conventional, kanamycin-based system for alfalfa Agrobacterium-mediated transformation. The hemL and NptII genes were placed together into a T-DNA under the control of identical promoters and terminators. We show that the gabaculine-based system is more efficient than the conventional, kanamycin-based system. The inheritance of hemL was Mendelian, and no obvious phenotypic effect of its expression was observed.     

Efficient deletion of LoxP-flanked selectable marker genes from the genome of transgenic pigs by an engineered Cre recombinase

Genetically modified (GM) pigs hold great promises for pig genetic improvement, human health and life science. When GM pigs are produced, selectable marker genes (SMGs) are usually introduced into their genomes for host cell or animal recognition. However, the SMGs that remain in GM pigs might have multiple side effects. To avoid the possible side effects caused by the SMGs, they should be removed from the genome of GM pigs before their commercialization. The Cre recombinase is commonly used to delete the LoxP sites-flanked SMGs from the genome of GM animals. Although SMG-free GM pigs have been generated by Cre-mediated recombination, more efficient and cost-effective approaches are essential for the commercialization of SMG-free GM pigs. In this article we describe the production of a recombinant Cre protein containing a cell-penetrating and a nuclear localization signal peptide in one construct. This engineered Cre enzyme can efficiently excise the LoxP-flanked SMGs in cultured fibroblasts isolated from a transgenic pig, which then can be used as nuclear donor cells to generate live SMG-free GM pigs harboring a desired transgene by somatic cell nuclear transfer. This study describes an efficient and far-less costly method for production of SMG-free GM pigs.

     

An introduction to DNA chips: principles, technology, applications and analysis

This review describes the recently developed GeneChip technology that provides efficient access to genetic information using miniaturised, high-density arrays of DNA or oligonucleotide probes. Such microarrays are powerful tools to study the molecular basis of interactions on a scale that would be impossible using conventional analysis. The recent development of the microarray technology has greatly accelerated the investigation of gene regulation. Arrays are mostly used to identify which genes are turned on or off in a cell or tissue, and also to evaluate the extent of a gene's expression under various conditions. Indeed, this technology has been successfully applied to investigate simultaneous expression of many thousands of genes and to the detection of mutations or polymorphisms, as well as for their mapping and sequencing.     

利用Cre/LoxP系统删除转基因山羊体内的选择标记基因

在制备转基因家畜过程中的一个关键步骤是使用选择标记基因 (Selectable marker genes,SMGs) 将转基因整合细胞从大量的正常细胞中筛选出来,这导致了SMGs整合入家畜的基因组内持续传递给后代。SMGs已被证明能够显著影响基因组内整合位点处的基因调控,也增加了对转基因动物安全评价的复杂性。为了确定转基因山羊制备过程中SMGs的删除时机和删除方法,在体细胞克隆前后两个时段内,利用Cre/loxP系统删除SMGs的可行性,同时比较了蛋白转导和质粒共转染两种Cre导入方式的删除效率。结果表明：尽管在首次对山羊成纤维细胞进行遗传修饰后即可进行SMGs删除,但两次遗传修饰导致细胞严重老化,无法用于后续的体细胞克隆羊制备。在转基因山羊的成体细胞中删除SMGs不存在上述问题,成功率高,缺点是试验周期长、耗资增大。Cre表达质粒瞬时转染能够删除SMGs,但有超过30%的无SMGs细胞克隆中整合有质粒序列。TAT-CRE蛋白质转导方法可以避免引入的新外源基因,SMGs删除率达到43.9%~72.8%,是一种较佳的SMGs删除手段。     

pSAT RNA interference vectors: a modular series for multiple gene down-regulation in plants

RNA interference (RNAi) is a powerful tool for functional gene analysis, which has been successfully used to down-regulate the levels of specific target genes, enabling loss-of-function studies in living cells. Hairpin (hp) RNA expression cassettes are typically constructed on binary plasmids and delivered into plant cells by Agrobacterium-mediated genetic transformation. Realizing the importance of RNAi for basic plant research, various vectors have been developed for RNAi-mediated gene silencing, allowing the silencing of single target genes in plant cells. To further expand the collection of available tools for functional genomics in plant species, we constructed a set of modular vectors suitable for hpRNA expression under various constitutive promoters. Our system allows simple cloning of the target gene sequences into two distinct multicloning sites and its modular design provides a straightforward route for replacement of the expression cassette's regulatory elements. More importantly, our system was designed to facilitate the assembly of several hpRNA expression cassettes on a single plasmid, thereby enabling the simultaneous suppression of several target genes from a single vector. We tested the functionality of our new vector system by silencing overexpressed marker genes (green fluorescent protein, DsRed2, and nptII) in transgenic plants. Various combinations of hpRNA expression cassettes were assembled in binary plasmids; all showed strong down-regulation of the reporter genes in transgenic plants. Furthermore, assembly of all three hpRNA expression cassettes, combined with a fourth cassette for the expression of a selectable marker, resulted in down-regulation of all three different marker genes in transgenic plants. This vector system provides an important addition to the plant molecular biologist's toolbox, which will significantly facilitate the use of RNAi technology for analyses of multiple gene function in plant cells.     

高等植物叶绿体基因组转化的应用

叶绿体基因组转化技术由于其独特的优越性,现已成为植物基因工程的研究热点。本文简单介绍了叶绿体基因组转化技术的原理和方法;并重点综述了该技术在基础研究和实践中的应用。这些应用主要包括利用叶绿体基因组转化技术进行Rubisco的组装,叶绿体基因结构、转录、翻译和RNA编辑等研究;利用叶绿体作为生物反应器生产人生长激素、霍乱毒素抗体、聚羟基丁酸脂和生物弹性蛋白等;获得抗虫、抗病、抗除草剂和耐旱的转基因植物;以及降低转基因植物的外源基因扩散等。     

Targeted gene expression by the Gal4-UAS system in zebrafish

Targeted gene expression by the Gal4-UAS system is a powerful methodology for analyzing function of genes and cells in vivo and has been extensively used in genetic studies in Drosophila . On the other hand, the Gal4-UAS system had not been applied effectively to vertebrate systems for a long time mainly due to the lack of an efficient transgenesis method. Recently, a highly efficient transgenesis method using the medaka fish Tol2 transposable element was developed in zebrafish. Taking advantage of the Tol2 transposon system, we and other groups developed the Gal4 gene trap and enhancer trap methods and established various transgenic fish expressing Gal4 in specific cells. By crossing such Gal4 lines with transgenic fish lines harboring various reporter genes and effector genes downstream of UAS (upstream activating sequence), specific cells can be visualized and manipulated in vivo by targeted gene expression. Thus, the Gal4 gene trap and enhancer trap approaches together with various UAS lines should be important tools for investigating roles of genes and cells in vertebrates.     

Overexpression of membrane proteins from higher eukaryotes in yeasts

Heterologous expression and characterisation of the membrane proteins of higher eukaryotes is of paramount interest in fundamental and applied research. Due to the rather simple and well-established methods for their genetic modification and cultivation, yeast cells are attractive host systems for recombinant protein production. This review provides an overview on the remarkable progress, and discusses pitfalls, in applying various yeast host strains for high-level expression of eukaryotic membrane proteins. In contrast to the cell lines of higher eukaryotes, yeasts permit efficient library screening methods. Modified yeasts are used as high-throughput screening tools for heterologous membrane protein functions or as benchmark for analysing drug–target relationships, e.g., by using yeasts as sensors. Furthermore, yeasts are powerful hosts for revealing interactions stabilising and/or activating membrane proteins. We also discuss the stress responses of yeasts upon heterologous expression of membrane proteins. Through co-expression of chaperones and/or optimising yeast cultivation and expression strategies, yield-optimised hosts have been created for membrane protein crystallography or efficient whole-cell production of fine chemicals.     

Genome modifications in plant cells by custom-made restriction enzymes

Genome editing, i.e. the ability to mutagenize, insert, delete and replace sequences, in living cells is a powerful and highly desirable method that could potentially revolutionize plant basic research and applied biotechnology. Indeed, various research groups from academia and industry are in a race to devise methods and develop tools that will enable not only site-specific mutagenesis but also controlled foreign DNA integration and replacement of native and transgene sequences by foreign DNA, in living plant cells. In recent years, much of the progress seen in gene targeting in plant cells has been attributed to the development of zinc finger nucleases and other novel restriction enzymes for use as molecular DNA scissors. The induction of double-strand breaks at specific genomic locations by zinc finger nucleases and other novel restriction enzymes results in a wide variety of genetic changes, which range from gene addition to the replacement, deletion and site-specific mutagenesis of endogenous and heterologous genes in living plant cells. In this review, we discuss the principles and tools for restriction enzyme-mediated gene targeting in plant cells, as well as their current and prospective use for gene targeting in model and crop plants.     

农杆菌介导转基因植物T-DNA的整合方式

农杆菌介导的遗传转化已被广泛应用于植物转基因研究。作为外源基因的载体,农杆菌T-DNA片段在植物基因组中的整合方式,不仅影响外源基因的整合效率及稳定性,还会影响外源基因的表达特性。文章就农杆菌介导的T-DNA整合的两种主要模式、规律及相关研究手段进行综述,为农杆菌介导的转基因及T-DNA插入突变等相关研究提供借鉴。     

Transgenic plastids in basic research and plant biotechnology

Facile methods of genetic transformation are of outstanding importance for both basic and applied research. For many years, transgenic technologies for plants were restricted to manipulations of the nuclear genome. More recently, a second genome of the plant cell has become amenable to genetic engineering: the prokaryotically organized circular genome of the chloroplast. The possibility to directly manipulate chloroplast genome-encoded information has paved the way to detailed in vivo studies of virtually all aspects of plastid gene expression. Moreover, plastid transformation technologies have been intensely used in functional genomics by performing gene knockouts and site-directed mutageneses of plastid genes. These studies have contributed greatly to our understanding of the physiology and biochemistry of biogenergetic processes inside the plastid compartment. Plastid transformation technologies have also stirred considerable excitement among plant biotechnologists, since transgene expression from the plastid genome offers a number of most attractive advantages, including high-level foreign protein expression and transgene containment due to lack of pollen transmission. This review describes the generation of plants with transgenic plastids, summarizes our current understanding of the transformation process and highlights selected applications of transplastomic technologies in basic and applied research.     

Molecular insights into the evolution of crop plants

The domestication and improvement of crop plants have long fascinated evolutionary biologists, geneticists, and anthropologists. In recent years, the development of increasingly powerful molecular and statistical tools has reinvigorated this now fast-paced field of research. In this paper, we provide an overview of how such tools have been applied to the study of crop evolution. We also highlight lessons that have been learned in light of a few long-standing and interrelated hypotheses concerning the origins of crop plants and the nature of the genetic changes underlying their evolution. We conclude by discussing compelling evolutionary genomic approaches that make possible the efficient and unbiased identification of genes controlling crop-related traits and provide further insight into the actual timing of selection on particular genomic regions.     

Surrogate reporters for enrichment of cells with nuclease-induced mutations

Zinc-finger nucleases (ZFNs) and TAL-effector nucleases (TALENs) are powerful tools for creating genetic modifications in eukaryotic cells and organisms. But wild-type and mutant cells that contain genetic modifications induced by these programmable nucleases are often phenotypically indistinguishable, hampering isolation of mutant cells. Here we show that transiently transfected episomal reporters encoding fluorescent proteins can be used as surrogate genes for the efficient enrichment of endogenous gene-modified cells by flow cytometry.     

Localizing protein-protein interactions by bimolecular fluorescence complementation in planta

The application of novel assays for basic cell research is tightly linked to the development of easy-to-use and versatile tools and protocols for implementing such technologies for a wide range of applications and model species. The bimolecular fluorescence complementation (BiFC) assay is one such novel method for which tools and protocols for its application in plant cell research are still being developed. BiFC is a powerful tool which enables not only detection, but also visualization and subcellular localization of protein–protein interactions in living cells. Here we describe the application of BiFC in plant cells while focusing on the use of our versatile set of vectors which were specifically designed to facilitate the transformation, expression and imaging of protein–protein interactions in various plant species. We discuss the considerations of using our system in various plant model systems, the use of single versus multiple expression cassettes, the application of our vectors using various transformation methods and the use of internal fluorescent markers which can assist in signal localization and easy data acquisition in living cells.