Agrobacterium-mediated plant transformation: the biology behind the "gene-jockeying" tool.

Agrobacterium tumefaciens and related Agrobacterium species have been known as plant pathogens since the beginning of the 20th century. However, only in the past two decades has the ability of Agrobacterium to transfer DNA to plant cells been harnessed for the purposes of plant genetic engineering. Since the initial reports in the early 1980s using Agrobacterium to generate transgenic plants, scientists have attempted to improve this "natural genetic engineer" for biotechnology purposes. Some of these modifications have resulted in extending the host range of the bacterium to economically important crop species. However, in most instances, major improvements involved alterations in plant tissue culture transformation and regeneration conditions rather than manipulation of bacterial or host genes. Agrobacterium-mediated plant transformation is a highly complex and evolved process involving genetic determinants of both the bacterium and the host plant cell. In this article, I review some of the basic biology concerned with Agrobacterium-mediated genetic transformation. Knowledge of fundamental biological principles embracing both the host and the pathogen have been and will continue to be key to extending the utility of Agrobacterium for genetic engineering purposes.     

Agrobacterium-Mediated Plant Transformation: the Biology behind the “Gene-Jockeying” Tool

Agrobacterium tumefaciens and related Agrobacterium species have been known as plant pathogens since the beginning of the 20th century. However, only in the past two decades has the ability of Agrobacterium to transfer DNA to plant cells been harnessed for the purposes of plant genetic engineering. Since the initial reports in the early 1980s using Agrobacterium to generate transgenic plants, scientists have attempted to improve this “natural genetic engineer” for biotechnology purposes. Some of these modifications have resulted in extending the host range of the bacterium to economically important crop species. However, in most instances, major improvements involved alterations in plant tissue culture transformation and regeneration conditions rather than manipulation of bacterial or host genes. Agrobacterium-mediated plant transformation is a highly complex and evolved process involving genetic determinants of both the bacterium and the host plant cell. In this article, I review some of the basic biology concerned with Agrobacterium-mediated genetic transformation. Knowledge of fundamental biological principles embracing both the host and the pathogen have been and will continue to be key to extending the utility of Agrobacterium for genetic engineering purposes.     

Agrobacterium is not alone: gene transfer to plants by viruses and other bacteria

Agrobacterium-mediated genetic transformation is the most widely used technology for obtaining the overexpression of recombinant proteins in plants. However, complex patent issues related to the use of Agrobacterium as a tool for plant genetic engineering and the general requirement of establishing transgenic plants can create obstacles in using this technology for speedy research and development and for agricultural improvements in many plant species. Recent studies addressing these issues have shown that virus-based vectors can be efficiently used for high transient expression of foreign proteins in transfected plants and that non-Agrobacterium bacterial species can be used for the production of transgenic plants, laying the foundation for alternative tools for future plant biotechnology.     

Partners-in-infection: host proteins involved in the transformation of plant cells by Agrobacterium

Genetic modification of plant cells by Agrobacterium is the only known natural example of DNA transport between kingdoms. While the bacterial factors involved in Agrobacterium infection have been relatively well characterized, studies of their host cellular partners are just beginning. Here, we describe the plant cell factors that might participate in Agrobacterium-mediated genetic transformation and discuss their possible roles in this process. Because Agrobacterium probably adapts existing cellular processes for its life cycle, identifying the host factors participating in Agrobacterium infection might contribute to a better understanding of such basic biological processes as cell communication, intracellular transport and DNA repair and recombination as well as help expand the host range of Agrobacterium as a genetic engineering tool.     

农杆菌T-复合物的形成与转运研究进展

在简要介绍农杆菌T-DNA转运全过程的基础上,结合作者近年的工作,重点对T-复合物的形成和T-复合物在农杆菌细胞内的转运机理的最新进展进行归纳和评述．农杆菌能够将其Ti质粒上的一段DNA以单链DNA-蛋白质复合物(简称T-复合物)的形式,通过其细胞两端的四型分泌系统(typeⅣ secretion system,T4SS)转运到宿主植物中,并使宿主发生遗传转化,因而农杆菌介导的T-DNA转运技术已成为应用最广泛的植物转基因技术,同时,由于转运T-复合物的T4SS也是某些质粒接合转移和许多病源微生物分泌致病效应蛋白的通道,因此,农杆菌T-DNA转运机理的研究受到了广泛的重视和关注,使得这方面的研究进展非常迅速．     

Agrobacterium-mediated gene delivery and the biology of hostrange limitations

Insertion of foreign DNA into Ti plasmid-derived vectors in Agrobacterium tumefaciens is currently the most frequently used strategy for generating transgenic plants in a wide variety of species. Limitations of the host range of Agrobacterium restrict its usefulness in many cases, particularly when dealing with monocotyledonous plants. The objective of this presentation is to briefly discuss the efficiency of the transformation process utilized by Agrobacterium tumefaciens , potential barriers to efficient transformation by Agrobacterium that result in limitation of its useful host range, and how an understanding of the successful Agrobacterium /plant cell interaction might lead to advances in a variety of DNA delivery methodologies.     

T-DNA-mediated transfer of Agrobacterium tumefaciens chromosomal DNA into plants

Besides the well-documented integration of DNA flanked by the transfer DNA borders, occasional insertion of fragments from the tumor-inducing plasmid into plant genomes has also been reported during Agrobacterium tumefaciens-mediated transformation. We demonstrate that large (up to approximately 18 kb) gene-bearing fragments of Agrobacterium chromosomal DNA (AchrDNA) can be integrated into Arabidopsis thaliana genomic DNA during transformation. One in every 250 transgenic plants may carry AchrDNA fragments. This has implications for horizontal gene transfer and indicates a need for greater scrutiny of transgenic plants for undesired bacterial DNA.     

Agrobacterium proteins VirD2 and VirE2 mediate precise integration of synthetic T-DNA complexes in mammalian cells

Agrobacterium tumefaciens-mediated plant transformation, a unique example of interkingdom gene transfer, has been widely adopted for the generation of transgenic plants. In vitro synthesized transferred DNA (T-DNA) complexes comprising single-stranded DNA and Agrobacterium virulence proteins VirD2 and VirE2, essential for plant transformation, were used to stably transfect HeLa cells. Both proteins positively influenced efficiency and precision of transgene integration by increasing overall transformation rates and by promoting full-length single-copy integration events. These findings demonstrate that the virulence proteins are sufficient for the integration of a T-DNA into a eukaryotic genome in the absence of other bacterial or plant factors. Synthetic T-DNA complexes are therefore unique protein:DNA delivery vectors with potential applications in the field of mammalian transgenesis.     

A transformation procedure for recalcitrant tomato by addressing transgenic plant-recovery limiting factors

Agrobacterium tumefaciens technology is the battle horse for tomato genetic transformation. However, tomato varieties with low regeneration capacity are very difficult to transform. In the past, tomato transformation through Agrobacterium infection was focused on varieties capable of high regeneration yield, while successful transformation of low regenerable cultivars has not been reported. The genotype response to tissue culture conditions is believed to drive the frequency of regeneration of transgenic plant, whereas the capacity for cell proliferation could determine the transformation efficiency through this technology. The Campbell-28 cultivar is an example of constraints arising from a high morphogenetic potential with low conversion compared to normal plants. In the present work the roles that contribute to improved transgenic plant recovery from this recalcitrant variety were explored for factors like Agrobacterium concentration and antibiotics for bacterial removal and transformant selection. Analysis of the efficiency from independent transformation experiments revealed a more than twofold increase of transformant regeneration after selection on ammonium glufosinate compared to kanamycin selection, showing a transformation efficiency of 21.5%.     

An efficient Agrobacterium-mediated transient transformation of Arabidopsis

Agrobacterium tumefaciens-mediated transient transformation has been a useful procedure for characterization of proteins and their functions in plants, including analysis of protein-protein interactions. Agrobacterium-mediated transient transformation of Nicotiana benthamiana by leaf infiltration has been widely used due to its ease and high efficiency. However, in Arabidopsis this procedure has been challenging. Previous studies suggested that this difficulty was caused by plant immune responses triggered by perception of Agrobacterium. Here, we report a simple and robust method for Agrobacterium-mediated transient transformation in Arabidopsis. AvrPto is an effector protein from the bacterial plant pathogen Pseudomonas syringae that suppresses plant immunity by interfering with plant immune receptors. We used transgenic Arabidopsis plants that conditionally express AvrPto under the control of a dexamethasone (DEX)-inducible promoter. When the transgenic plants were pretreated with DEX prior to infection with Agrobacterium carrying a β-glucuronidase (GUS, uidA) gene with an artificial intron and driven by the CaMV 35S promoter, transient GUS expression was dramatically enhanced compared to that in mock-pretreated plants. This transient expression system was successfully applied to analysis of the subcellular localization of a cyan fluorescent protein (CFP) fusion and a protein-protein interaction in Arabidopsis. Our findings enable efficient use of Agrobacterium-mediated transient transformation in Arabidopsis thaliana.     

根癌农杆菌介导的黄瓜转基因研究进展

黄瓜Cucumis sativus是世界性的重要蔬菜作物。农杆菌介导的转基因技术是研究植物基因功能及品种改良的重要手段。为进一步加快黄瓜的转基因研究和育种进程,文中针对农杆菌介导的黄瓜遗传转化方法,从黄瓜再生能力的影响因素、遗传转化条件和过程中各类添加物质等方面,阐述了根癌农杆菌介导的黄瓜转基因研究进展及存在的问题,并对提高黄瓜遗传转化效率和安全筛选标记的应用等前景进行了展望,以期为黄瓜抗逆育种和果实品质改良等研究提供参考。     

影响根癌农杆菌转化的因素及其在单子叶作物上的应用

在植物转基因方法中,根癌农杆菌介导的遗传转化应用最为广泛,进一步提高其转化频率并扩大其宿主范围到禾谷类作物是人们所关注的问题。有多种因素影响根癌农杆菌的转化频率,包括植物的受伤反应、细菌的吸附、致病基因的诱导、植物细胞ＤＮＡ合成及修复的活力、外植体的状态等。最近的研究结果证明在适宜的条件下,根癌农杆菌还是可以有效地转化禾谷类作物。本文试就这两方面的研究进展作一论述。     

Transfer of T-DNA and Vir proteins to plant cells by Agrobacterium tumefaciens induces expression of host genes involved in mediating transformation and suppresses host defense gene expression

Agrobacterium tumefaciens is a plant pathogen that incites crown gall tumors by transferring to and expressing a portion of a resident plasmid in plant cells. Currently, little is known about the host response to Agrobacterium infection. Using suppressive subtractive hybridization and DNA macroarrays, we identified numerous plant genes that are differentially expressed during early stages of Agrobacterium-mediated transformation. Expression profiling indicates that Agrobacterium infection induces plant genes necessary for the transformation process while simultaneously repressing host defense response genes, thus indicating successful utilization of existing host cellular machinery for genetic transformation purposes. A comparison of plant responses to different strains of Agrobacterium indicates that transfer of both T-DNA and Vir proteins modulates the expression of host genes during the transformation process.     

Application of novel nanotechnology strategies in plant biotransformation: a contemporary overview

During the past epoch we have gone through the remarkable progress in plant gene transformation technology. The production of transgenic plants is considered as a valuable tool in plant research and the technology is extensively applied in phytomedicines and agricultural research. Gene transformation in plants is normally carried out by Agrobacterium species, application of some chemicals and physical techniques (electroporation, microprojectile, etc.). Now a days with better efficacy and reproducibility, novel technologies for the direct gene transfer like liposome, positively charged liposome (lipofectin) and nanoparticle based delivery systems are used for genetic transformation of plants. In this review, we have enlightened the novel nanotechnologies like liposome, Carbon nano-tube and nanoparticles with their current status and future prospects in transgenic plant development. Moreover, we have also highlighted the limitations of conventional techniques of gene transfer. Furthermore, we have tried to postulate innovative ideas on the footprints of established nanotechnology and chemical based strategy with improved efficacy, reproducibility and accuracy along with less time consumption.     

月季组织培养和遗传转化体系的研究进展

月季通过器官和体细胞胚发生途径都可以获得再生植株,在遗传转化中主要是利用体细胞胚作为转化受体。目前,利用农杆菌介导法和基因枪法已成功将外源基因如报告基因、抗病基因和改变花色的基因等导入月季基因组中。本文对近年来月季组织培养和转基因研究进展进行了综述,为建立月季高效遗传转化体系奠定了理论基础。     

植物的遗传转化及其应用(英文)

近年来,植物遗传转化研究有了长足的发展。已经达到能够通过简单的遗传控制手段研究具有新表现型的植物,甚至达到进入商业化的程度。这些手段包括植物生物学的主要研究技术以及植物组织培养和树种改良的一些实用方法。尽管采用农瘤杆菌和鸟枪法等技术的植物遗传转化系统已经得到了广泛的应用,但是在如何开发具有能够得到控制表达的转基因高产植物方面,在如何使所得到的转基因植物远离遗传危害等方面,目前的转化系统遇到了极大的技术挑战。已经提出了各种各样的方法用于将新基因稳定地导入120多种不同植物的核基因组。本文将讨论这些遗传转化系统所需的生物学要求和实际应用方面的需求、基因转化和转基因表达的研究策略、遗传转化植物的鉴定以及转基因植物与大众的认可。本文将分为七个部分加以讨论:一、导言;二 、基因转化到细胞里的方法;三、植物遗传转化策略;四、植物遗传转化的鉴定;五、植物遗传转化的实际应用;六、转基因植物与环境;七、未来植物遗传转化的需求与发展方向。     

Arabidopsis ovule is the target for Agrobacterium in planta vacuum infiltration transformation

The visual marker GUS has been utilized in this study to understand the Arabidopsis thaliana vacuum infiltration transformation process by Agrobacterium tumefaciens. High transformation frequencies of up to 394 transgenic seeds per infiltrated plant were achieved. The results showed that the majority of the transgenic seeds from single infiltrated plants were from independent transformation events based on Southern analysis, progeny segregation, distribution of transgenic seeds throughout the infiltrated plants and the microscopic analysis of GUS expression in ovules of infiltrated plants. GUS expression in mature pollen and anthers was monitored daily from 0 to 12 days post-infiltration. In addition, all ovules from a single infiltrated plant were examined every other day. GUS expression frequencies of up to 1% of pollen were observed 3-5 days post-infiltration, whereas frequencies of up to 6% were detected with ovules of unopened flowers 5-11 days post-infiltration. Most importantly, transgenic seeds were obtained only from genetic crosses using infiltrated plants as the pollen recipient but not the pollen donor, demonstrating Agrobacterium transformation through the ovule pathway.     

Transgenic strategies for genetic improvement of Basmati rice

Transgenic approach offers an attractive alternative to conventional techniques for the genetic improvement of Basmati rice because they enable the introduction of one or more genes into a leading cultivar without affecting its genetic background. During the last ten years, a rapid progress has been made towards the development of transformation methods in rice. Several transformation methods including Agrobacterium, biolistic, and DNA uptake by protoplasts, have been employed to produce transgenic rice. An array of useful genes is now available and many of these have already been transferred in rice to improve the resistance against biotic and abiotic stresses. In Basmati rice, a beginning has already been made regarding the development of tissue culture protocols, transformation methods and production of useful transgenic plants. The application and future prospects of transformation technology to engineer the resistance against insect pests (stem borer, leaf folder, brown plant hopper, gall midge), fungal diseases (blast, bakanae/foot, rot), bacterial diseases (bacterial leaf blight, sheath blight), abiotic stresses (salinity and drought) and improved nutritional quality (accumulation of provitamin A and essential amino acids in endosperm) in Basmati rice, have been addressed.     

Agrobacterium tumefaciens as an agent of disease

Twenty-six years ago it was found that the common soil bacterium Agrobacterium tumefaciens is capable of extraordinary feats of interkingdom genetic transfer. Since this discovery, A. tumefaciens has served as a model system for the study of type IV bacterial secretory systems, horizontal gene transfer and bacterial-plant signal exchange. It has also been modified for controlled genetic transformation of plants, a core technology of plant molecular biology. These areas have often overshadowed its role as a serious, widespread phytopathogen - the primary driver of the first 80 years of Agrobacterium research. Now, the diverse areas of A. tumefaciens research are again converging because new discoveries in transformation biology and the use of A. tumefaciens vectors are allowing the development of novel, effective biotechnology-based strategies for the control of crown gall disease.