A short history of plant biotechnology

The foundations of modern plant biotechnology can be traced back to the Cell Theory of Schleiden (Arch Anat Physiol Wiss Med (J Müller) 1838:137–176, 1838) and Schwann (Mikroscopische Untersuchungen über die übereinstimmung in der Struktur und dem Wachstum des Tiere und Pflanzen. W Engelmann: Leipzig No 176, 1839), which recognized the cell as the primary unit of all living organisms. The concept of cellular totipotency, which was inherent in the Cell Theory and forms the basis of plant biotechnology, was further elaborated by Haberlandt (Sitzungsber K Preuss Akad Wiss Wien, Math-Naturwiss 111:69–92, 1902), who predicted the production of somatic embryos from vegetative cells. This brief historical account traces the development of technologies for the culture, regeneration and transformation of plants that led to the production of transgenic crops which have become central to the many applications of plant biotechnology, and celebrates the pioneering men and women whose trend-setting contributions made it all possible. Opening Plenary Address delivered at the international conference on “Plants for Human Health in the Post-Genome Era”, held August 26–29, 2007, in Helsinki, Finland.     

<Emphasis Type="Italic">Rhizobia species</Emphasis>: A Boon for “Plant Genetic Engineering”

Since past three decades new discoveries in plant genetic engineering have shown remarkable potentials for crop improvement. Agrobacterium Ti plasmid based DNA transfer is no longer the only efficient way of introducing agronomically important genes into plants. Recent studies have explored a novel plant genetic engineering tool, Rhizobia sp., as an alternative to Agrobacterium, thereby expanding the choice of bacterial species in agricultural plant biotechnology. Rhizobia sp. serve as an open license source with no major restrictions in plant biotechnology and help broaden the spectrum for plant biotechnologists with respect to the use of gene transfer vehicles in plants. New efficient transgenic plants can be produced by transferring genes of interest using binary vector carrying Rhizobia sp. Studies focusing on the interactions of Rhizobia sp. with their hosts, for stable and transient transformation and expression of genes, could help in the development of an adequate gene transfer vehicle. Along with being biologically beneficial, it may also bring a new means for fast economic development of transgenic plants, thus giving rise to a new era in plant biotechnology, viz. “Rhizobia mediated transformation technology.”     

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.     

Biotechnological applications of plant cells in culture

For many workers, the most exciting recent advances in the realm of plant cell biotechnology, center on results obtained from experiments concerned with the genetic engineering of plant cells. Various groups of workers have managed to introduce new genetic material into plant cells, using Ti-plasmids (or modified Ti-plasmids) from Agrobacterium tumefaciens. This genetic material has been expressed (with varying degrees of efficiency), in each case. Thus the way may possibly be coming clear to produce plant cell cultures, or whole plants with entirely new or novel properties. Other areas in which progress has been made, are in the design of media conditions to promote secondary product formation, and in ways of immobilizing plant cells and enzymes, to achieve efficient secondary product formation.     

促进植物高效遗传转化的发育调节因子及其在玉米中的应用进展*

高效遗传转化技术体系的建立对植物功能基因组学研究和作物新品种的培育均具有促进作用,目前,再生效率低下是限制许多植物高效遗传转化体系建立的主要技术屏障之一。随着对植物分生组织和体细胞胚形成过程研究的深入,鉴定到了一些关键调控基因,统称为发育调节因子。发育调节因子应用于植物遗传转化后,可以有效改善植物分生组织诱导和再生能力,为提高遗传转化效率提供了重要机遇。综述了7类发育调节因子在提高植物遗传转化效率中的研究进展,重点介绍了其中3类在促进玉米遗传转化中的应用,最后展望了建立植物高效遗传转化体系的发展方向。     

Medicinal biotechnology in the genus <Emphasis Type="Italic">scutellaria</Emphasis>

Plant-based medicines have an important role in the lives of millions of people. The ancient knowledge of the use of plants as medicines has led to the discovery of many important western pharmaceuticals, and the popularity of whole plant preparations for a range of therapeutic applications is growing rapidly. However, there are many challenges in the production of plant-based medicines, many of which put both the consumer and the plant populations at risk. Modern biotechnology can be optimized to mass-produce plants of specific chemical composition for use as particular treatments and applications. In this review, we have used one of the most important medicinal plant genera, Scutellaria, as a model to assess the potential of applications of biotechnology for the improvement of medicinal plants.     

An in vivo Transient Expression System Can Be Applied for Rapid and Effective Selection of Artificial MicroRNA Constructs for Plant Stable Genetic Transformation

The utility of artificial microRNAs (amiRNAs) to induce loss of gene function has been reported for many plant species, but expression efficiency of the different amiRNA constructs in different transgenic plants was less predictable. In this study, expressions of amiRNAs through the gene backbone of Arabidopsis miR168a were examined by both Agrobacterium-mediated transient expression and stable plant genetic transformation. A corresponding trend in expression of amiRNAs by the same amiRNA constructs between the transient and the stable expression systems was observed in the experiments. Plant genetic transformation of the constructs that were highly expressible in amiRNAs in the transient agro-infiltration assays resulted in generation of transgenic lines with high level of amiRNAs. This provides a simple method for rapid and effective selection of amiRNA constructs used for a time-consuming genetic transformation in plants.     

蓖麻生物工程研究进展

蓖麻是一种高蓄能植物和工业原料植物,具有很大的开发利用价值。本文从组织培养和遗传转化两个方面并结合本实验室的工作综述了蓖麻生物工程研究的最新进展。在蓖麻组织培养方面,不同的外植体中以成熟种子的胚轴最适宜,而在不同激素中以TDZ诱导丛生芽的效率最高,并以此为基础建立了蓖麻离体再生体系。在遗传转化方面,不同的转化方法中以农杆菌介导法最适合蓖麻转化。蓖麻胚轴对卡那霉素不敏感,潮霉素是蓖麻转化的适宜筛选剂。文中指出了蓖麻生物工程研究中存在的问题,并对应用生物技术培育蓖麻新品种和促进蓖麻生产的可能性进行了讨论。     

Agrobacterium-mediated genetic transformation of plants: biology and biotechnology

Agrobacterium-mediated genetic transformation is the dominant technology used for the production of genetically modified transgenic plants. Extensive research aimed at understanding and improving the molecular machinery of Agrobacterium responsible for the generation and transport of the bacterial DNA into the host cell has resulted in the establishment of many recombinant Agrobacterium strains, plasmids and technologies currently used for the successful transformation of numerous plant species. Unlike the role of bacterial proteins, the role of host factors in the transformation process has remained obscure for nearly a century of Agrobacterium research, and only recently have we begun to understand how Agrobacterium hijacks host factors and cellular processes during the transformation process. The identification of such factors and studies of these processes hold great promise for the future of plant biotechnology and plant genetic engineering, as they might help in the development of conceptually new techniques and approaches needed today to expand the host range of Agrobacterium and to control the transformation process and its outcome during the production of transgenic plants.     

月季的植株再生及遗传转化研究进展

本文对近20年月季植株再生和转基因研究进展进行了较为系统的回顾和总结.月季通过器官和体细胞胚发生途径都能再生植株,但遗传转化主要是利用体细胞胚发生途径.通过农杆菌介导法和基因枪法,外源基因如报告基因、抗病基因和改变花色的基因等已转化成功.文章还对今后月季转基因研究的方向进行了讨论.     

In vitro regeneration and genetic manipulation of grasses

Regeneration of plants from cultured cells is an important and essential component of plant biotechnology. Advances in the recovery of plants from cultured cells and protoplasts of grasses, and in genetic transformation provide challenging opportunities for the genetic manipulation and improvement of this most important group of food plants.     

In vitro chili pepper biotechnology

Summary Chili pepper is an important horticultural crop that can surely benefit from plant biotechnology. However, although it is a Solanaceous member, developments in plant cell, tissue, and organ culture, as well as on plant genetic transformation, have lagged far behind those achieved for other members of the same family, such as tobacco (Nicotiana tabacum), tomato (Lycopersicon esculentum), and potato (Solanum tuberosum), species frequently used as model systems because of their facility to regenerate organs and eventually whole plants in vitro, and also for their ability to be genetically engineered by the currently available transformation methods. Capsicum members have been shown to be recalcitrant to differentiation and plant regeneration under in vitro conditions, which in turn makes it very difficult or inefficient to apply recombinant DNA technologies via genetic transformation aimed at genetic improvement against pests and diseases. Some approaches, however, have made possible the regeneration of chili pepper plants from in vitro-cultured cells, tissues, and organs through organogenesis or embryogenesis. Anther culture has been successfully applied to obtain haploid and doubledhaploid plants. Organogenic systems have been used for in vitro micropropagation as well as for genetic transformation. Application of both tissue culture and genetic transformation techniques have led to the development of chili pepper plants more resistant to at least one type of virus. Cell and tissue cultures have been applied successfully to the selection of variant cells exhibiting increased resistance to abiotic stresses, but no plants exhibiting the selected traits have been regenerated. Production of capsaicinoids, the hot principle of chili pepper fruits, by cells and callus tissues has been another area of intense research. The advances, limitations, and applications of chili pepper biotechnology are discussed.     

The Application of Biotechnology to Orchids

This review provides an informative and broad overview of orchid biotechnology, addressing several important aspects such as molecular systematics, modern breeding, in vitro morphogenesis, protoplast culture, flowering control, flower color, somaclonal variation, orchid mycorrhiza, pathogen resistance, virus diagnosis and production of virus-free plants, functional genomics, genetic transformation, conservation biotechnology and pharmaceutical biotechnology. This resource will provide valuable insight to researchers who are involved in orchid biology and floriculture, using biotechnology to advance research objectives. Producing an improved orchid through biotechnology for industrial purposes or to serve as a model plant for pure and applied sciences is well within reach and many of the current techniques and systems are already employed at the commercial production level.     

植物耐热相关基因研究进展

植物受到高温胁迫时,会激活某些特定基因的表达,从而增强植物的耐热性。近年来,随着生物技术的不断发展,植物耐热相关基因被相继克隆并转化植物体。本文对植物耐热的分子机制、相关基因的克隆、耐热性基因工程研究进展进行了综述,并提出了植物耐热基因工程的研究方向。     

利用有性途径的植物转化

近年来 ,植物基因工程技术取得了重要进展 ,在农作物品种改良和育种方面发挥越来越重要的作用。然而 ,目前植物遗传转化所采用的受体系统 ,大都依赖于细胞组织培养技术才能获得转基因植株。其中 ,基因型限制和遗传变异是限制该技术发展和应用的两大障碍。因此 ,一些研究者试图避开组织培养和植株再生过程 ,利用植物有性生殖途径进行转化 ,并取得了一系列成果。这些方法包括以下方面 :(1 )利用花粉粒或花粉管作为转化DNA的载体 ;(2 )将外源DNA导入子房或胚珠中 ;(3 )以精、卵细胞、合子作为转化受体。这些方法利用了高等植物的有性生殖机制和胚胎发育过程 ,避免了无性繁殖过程中的遗传变异、植株再生困难及转基因植株嵌合等问题。该文归纳综合了该研究领域所取得的成果和最新进展 ,并对这些方法进行了评价及其发展趋势进行了分析。     

Biotechnological advancement in genetic improvement of broccoli (<Emphasis Type="Italic">Brassica oleracea</Emphasis> L. var. <Emphasis Type="Italic">italica</Emphasis>), an important vegetable crop

With the advent of molecular biotechnology, plant genetic engineering techniques have opened an avenue for the genetic improvement of important vegetable crops. Vegetable crop productivity and quality are seriously affected by various biotic and abiotic stresses which destabilize rural economies in many countries. Moreover, absence of proper post-harvest storage and processing facilities leads to qualitative and quantitative losses. In the past four decades, conventional breeding has significantly contributed to the improvement of vegetable yields, quality, post-harvest life, and resistance to biotic and abiotic stresses. However, there are many constraints in conventional breeding, which can only be overcome by advancements made in modern biology. Broccoli (Brassica oleracea L. var. italica) is an important vegetable crop, of the family Brassicaceae; however, various biotic and abiotic stresses cause enormous crop yield losses during the commercial cultivation of broccoli. Thus, genetic engineering can be used as a tool to add specific characteristics to existing cultivars. However, a pre-requisite for transferring genes into plants is the availability of efficient regeneration and transformation techniques. Recent advances in plant genetic engineering provide an opportunity to improve broccoli in many aspects. The goal of this review is to summarize genetic transformation studies on broccoli to draw the attention of researchers and scientists for its further genetic advancement.     

药用植物转基因研究进展

随着医疗事业的发展,药用植物的遗传转化越来越成为人们关注的焦点.近年来药用植物的遗传转化取得了很大进展,已成功培育了多种转基因药用植物.从遗传转化方法、转化受体和转化的目的基因等方面来论述了近年来药用植物转基因的研究进展,并对以后的发展提出了展望.     

Systemic Agrobacterium tumefaciens-mediated transfection of viral replicons for efficient transient expression in plants

Plant biotechnology relies on two approaches for delivery and expression of heterologous genes in plants: stable genetic transformation and transient expression using viral vectors. Although much faster, the transient route is limited by low infectivity of viral vectors carrying average-sized or large genes. We have developed constructs for the efficient delivery of RNA viral vectors as DNA precursors and show here that Agrobacterium-mediated delivery of these constructs results in gene amplification in all mature leaves of a plant simultaneously (systemic transfection). This process, called "magnifection", can be performed on a large scale and with different plant species. This technology combines advantages of three biological systems (the transfection efficiency of A. tumefaciens, the high expression yield obtained with viral vectors, and the post-translational capabilities of a plant), does not require genetic modification of plants and is faster than other existing methods.     

Characterization and promoter activity of chromoplast specific carotenoid associated gene (CHRC) from Oncidium Gower Ramsey

Tissue-specific promoters are required for plant molecular breeding to drive a target gene in the appropriate location in plants. A chromoplast-specific, carotenoid-associated gene (OgCHRC) and its promoter (Pchrc) were isolated from Oncidium orchid and characterized. Northern blot analysis revealed that OgCHRC is specifically expressed in flowers, not in roots and leaves. Transient expression assay of Pchrc by bombardment transformation confirmed its differential expression pattern in floral tissues of different horticulture plants and cell-type location in conical papillate cells of adaxial epidermis of flower. These results suggest that Pchrc could serve as a useful tool in ornamental plant biotechnology to modify flower color.