叶绿体转化及其用于疫苗表达研究的最新进展

随着植物转基因研究的不断深入,核基因组转化的转基因沉默现象严重影响了基因工程的应用效果。植物叶绿体遗传转化以叶绿体基因组为平台对植物进行遗传操作,外源基因定点整合及母性遗传特性能较好地解决"顺式失活"和"位置效应"等类的基因沉默问题和转基因逃逸等安全问题,成为植物基因工程发展的新方向,在工业、农业及医药生物领域发挥了重要作用,也为生产廉价、安全的植物疫苗提供了新思路。本文在简要介绍叶绿体转化的原理、转化方法与优势的基础上,重点综述了近年来通过该技术表达的一些重要的病毒抗原和细菌抗原。最后,对叶绿体转化技术在表达外源基因方面存在的问题进行分析。未来随着叶绿体基因表达、调控机制研究的逐渐深入及相关技术体系的日臻完善,叶绿体转化有望成为疫苗生产的生力军。     

叶绿体转化体系研究进展

叶绿体转化具有表达效率高,安全性高,遗传稳定,以及多基因可以同时转化等特点。真核或原核的外源基因都能在叶绿体中进行成功表达,至少有20种植物成功的进行了叶绿体转化。叶绿体作为生物反应器具有广阔的应用前景。     

叶绿体基因组在系统发育学及基因工程领域的应用

介绍了叶绿体基因组在系统发育学和基因工程这两个领域的应用研究进展：1)叶绿体基因组的DNA序列比较为植物系统发育学研究提供了可靠数据基础;2)叶绿体基因工程是高水平表达外源基因的重要途径之一,在生产医用蛋白、改良作物农艺性状和环境保护等方面有着广阔的应用前景。     

高等植物叶绿体表达重组蛋白研究进展

近年来,基因工程技术发展迅速,许多重组蛋白得以表达。其中利用植物生物反应器表达特异药物蛋白为人类一些重要疾病的预防和治疗提供了新途径。植物叶绿体遗传转化和表达系统成为目前植物生物反应器的研究热点。因结构和遗传上的特殊性,高等植物叶绿体在重组蛋白表达方面具有独特优势,外源基因表达量高、定点整合,而且叶绿体母系遗传特性保证了生物安全性。很多重要药用蛋白质在植物叶绿体中表达成功。烟草作为高等植物叶绿体转化模式植物,在疫苗抗原、抗体等药物蛋白和其他重要重组蛋白表达方面取得显著进展。高等植物叶绿体遗传转化也为叶绿体基因的表达和调控机制的研究提供新的技术和方法。文中从叶绿体遗传转化原理、载体构建、重组蛋白和重要药物蛋白在叶绿体中的表达以及重组蛋白表达对植物代谢和性状影响等多个角度,对高等植物叶绿体遗传转化体系研究的新进展进行了综述,以期为叶绿体表达平台的开发和重要药用蛋白质的表达提供新思路。     

高等植物的叶绿体转化系统及研究进展

在高等植物的细胞中 ,细胞核、叶绿体和线粒体都含有ＤＮＡ ,它们构成了既相对独立又相互联系的遗传系统。以细胞核为外源基因受体的植物基因工程已被广泛地应用于重要农作物的改良。但核基因转化仍存在一系列难以解决的问题 ,如细胞核基因组大、背景复杂 ;外源基因的表达效率低 ,后代不稳定 ;环境安全难以保证等。为克服核基因转化存在的不足 ,1 988年 ,Ｂｏｙｎｔｏｎ等[1] 以衣藻为材料用基因枪进行外源基因对叶绿体的转化 ,首次证实了叶绿体转化的可行性。这项工作使人们意识到植物的叶绿体不仅是光合作用的重要场所 ,也可以作为植物基…     

叶绿体基因工程研究的理想材料——衣藻

狭义的叶绿体基因工程主要是将目的基因经克隆、修饰后,与合适的表达元件（启动子、终止子、筛选标记基因等）及转化载体进行体外重组,并进而导入植物叶绿体中,通过同源重组,使之定点整合、稳定表达、稳定遗传并表现出目的性状的过程。广义的叶绿体基因工程则还包括叶...     

叶绿体转基因植物——一种新型生物反应器

叶绿体转基因植物作为生物反应器, 具有外源蛋白表达量高和环境安全性好等优点, 近年来呈现出诱人的发展前景。本文综述了叶绿体基因工程的优越性, 并重点介绍了叶绿体转基因植物作为生物反应器在生产疫苗、药用蛋白及生物可降解塑料等物质方面的最新研究进展。     

叶绿体转基因植物--一种新型生物反应器

叶绿体转基因植物作为生物反应器,具有外源蛋白表达量高和环境安全性好等优点,近年来呈现出诱人的发展前景。本文综述了叶绿体基因工程的优越性,并重点介绍了叶绿体转基因植物作为生物反应器在生产疫苗、药用蛋白及生物可降解塑料等物质方面的最新研究进展。     

叶绿体基因工程：一种植物生物技术的新方法

以叶绿体转化为主的叶绿体基因工程,与传统的基因工程技术细胞核转化相比,在外源基因表达水平和转基因植物安全性等方面有明显的优势, 尤其是在控制转基因沉默和遗传稳定性方面,可以互补核转化带来的局限性。因此,叶绿体基因工程是一种很具有发展前景的植物转基因技术,并在未来工农业生物技术领域发挥重要作用。本文着重在叶绿体转化技术主要特点,应用领域及其未来的发展前景等方面进行了简单评述。     

叶绿体遗传转化的研究进展

核转化技术是基因工程的主要方法,但其多方面的不安全性使人们把焦点转向了植物基因工程另一目标：叶绿体遗传转化。本文介绍了叶绿体基因及基因组;叶绿体遗传转化的原理和方法：叶绿体转化的优点。重点介绍了关于叶绿体遗传转化国内外研究新进展。     

Taming plastids for a green future

Plant genetic engineering will probably contribute to the required continued increase in agricultural productivity during the coming decades, and moreover, plants can potentially provide inexpensive production platforms for pharmaceuticals and nutraceuticals. With the advent of technologies for altering the genetic information inside chloroplasts, a new attractive target for genetic engineering has become available to biotechnologists. Potential advantages over conventional nuclear transformation include high transgene expression levels and increased biosafety because of maternal organelle inheritance in most crops. This review summarizes the state of the art in chloroplast genetic engineering and describes how reverse genetics approaches enhance our understanding of photosynthesis and other important chloroplast functions. Furthermore, promising strategies by which chloroplast genetic engineering might contribute to the successful modification of plant metabolism are discussed.     

叶绿体基因组研究进展

作为植物细胞器的重要组成部分和光合作用的器官,叶绿体在生物进化的漫长历史中发挥了重要作用.伴随着生物技术的深入发展,人们发现叶绿体基因组结构和序列的信息在揭示物种起源、进化演变及其不同物种之间的亲缘关系等方面具有重要价值.与此同时,比核转化具有明显优势的叶绿体转化技术在遗传改良、生物制剂的生产等方面显示出巨大潜力,而叶绿体基因组结构和序列分析则是叶绿体转化的基石.基于叶绿体的这些重要作用,收集整理了有关的资料,从几个方面归纳了本领域最近的研究进展,希望能使读者对迅速发展的叶绿体基因组研究有更全面的了解,以及对叶绿体基因组在物种的进化、遗传、系统发育关系等方面的作用有更深刻的认识,同时也希望对叶绿体转化技术的研究和广泛应用产生积极作用.     

Enslaved bacteria as new hope for plant biotechnologists

The most distinguishing feature of the plant cell is a DNA-containing organelle that sets plants apart from all other organisms: the chloroplast. Compelling evidence supports an endosymbiotic origin for chloroplasts. According to this theory, chloroplasts are descendants of formerly free-living cyanobacterial ancestors which entered an endosymbiotic relationship with a pre-eukaryotic cell and were ultimately integrated into the metabolism of the host cell. Chloroplasts retain many prokaryotic features and their gene expression system still closely resembles that of their eubacterial ancestors. During the past decade, our knowledge about chloroplast biology has benefited immensely from a most remarkable methodological breakthrough: the development of transformation technologies for chloroplast genomes. Moreover, recent advances in the manipulation of higher plant chloroplast genomes have created unprecedented opportunities for the genetic engineering of plants and promise to overcome many of the problems associated with conventional transgenic technologies. This review describes the state of the art in genetic engineering of higher plant chloroplast genomes and highlights the tremendous potential of these technologies for the biotechnology of the future. Received: 27 January 2000 / Received revision: 15 March 2000 / Accepted: 24 March 2000     

Advances in chloroplast engineering

The chloroplast is a pivotal organelle in plant cells and eukaryotic algae to carry out photosynthesis, which provides the primary source of the world＇s food. The expression of foreign genes in chloroplasts offers several advantages over their expression in the nucleus： high-level expression, transgene stacking in operons and a lack of epigenetic interference allowing stable transgene expression. In addition, transgenic chloroplasts are generally not transmitted through pollen grains because of the cytoplasmic localization. In the past two decades, great progress in chloroplast engineering has been made. In this paper, we review and highlight recent studies of chloroplast engineering, including chloroplast transformation procedures, controlled expression of plastid transgenes in plants, the expression of foreign genes for improvement of plant traits, the production of biopharmaceuticals, metabolic pathway engineering in plants, plastid transformation to study RNA editing, and marker gene excision system.     

Manipulation of the microalgal chloroplast by genetic engineering for biotechnological utilization as a green biofactory

The chloroplast is an essential organelle in microalgae for conducting photosynthesis, thus enabling the photoautotrophic growth of microalgae. In addition to photosynthesis, the chloroplast is capable of various biochemical processes for the synthesis of proteins, lipids, carbohydrates, and terpenoids. Due to these attractive characteristics, there has been increasing interest in the biotechnological utilization of microalgal chloroplast as a sustainable alternative to the conventional production platforms used in industrial biotechnology. Since the first demonstration of microalgal chloroplast transformation, significant development has occurred over recent decades in the manipulation of microalgal chloroplasts through genetic engineering. In the present review, we describe the advantages of the microalgal chloroplast as a production platform for various bioproducts, including recombinant proteins and high-value metabolites, features of chloroplast genetic systems, and the development of transformation methods, which represent important factors for gene expression in the chloroplast. Furthermore, we address the expression of various recombinant proteins in the microalgal chloroplast through genetic engineering, including reporters, biopharmaceutical proteins, and industrial enzymes. Finally, we present many efforts and achievements in the production of high-value metabolites in the microalgal chloroplast through metabolic engineering. Based on these efforts and advances, the microalgal chloroplast represents an economically viable and sustainable platform for biotechnological applications in the near future.     

高等植物叶绿体基因工程

叶绿体基因工程作为一项新技术具有一系列传统核基因工程所不具备的优点,在基础性及应用性研究中极具吸引力,已经成功应用于了解质体基因组,调控植物代谢系统,农作物抗旱、抗虫、抗病、抗除草剂及以植物为生物反应器生产抗体、疫苗等方面的研究.本文主要介绍叶绿体基因工程的原理、操作体系及其在高等植物中的应用.     

高等植物叶绿体基因工程

叶绿体基因工程作为一项新技术具有一系列传统核基因工程所不具备的优点,在基础性及应用性研究中极具吸引力,已经成功应用于了解质体基因组,调控植物代谢系统,农作物抗旱、抗虫、抗病、抗除草剂及以植物为生物反应器生产抗体、疫苗等方面的研究。本文主要介绍叶绿体基因工程的原理、操作体系及其在高等植物中的应用。     

The making of a chloroplast

Since its endosymbiotic beginning, the chloroplast has become fully integrated into the biology of the host eukaryotic cell. The exchange of genetic information from the chloroplast to the nucleus has resulted in considerable co‐ordination in the activities of these two organelles during all stages of plant development. Here, we give an overview of the mechanisms of light perception and the subsequent regulation of nuclear gene expression in the model plant Arabidopsis thaliana, and we cover the main events that take place when proplastids differentiate into chloroplasts. We also consider recent findings regarding signalling networks between the chloroplast and the nucleus during seedling development, and how these signals are modulated by light. In addition, we discuss the mechanisms through which chloroplasts develop in different cell types, namely cotyledons and the dimorphic chloroplasts of the C₄ plant maize. Finally, we discuss recent data that suggest the specific regulation of the light‐dependent phases of photosynthesis, providing a means to optimize photosynthesis to varying light regimes.