Introduction of bacterial metabolism into higher plants by polycistronic transgene expression

Multiple-gene transformation is required to improve or change plant metabolisms effectively; but this many-step procedure is time-consuming and costing. We succeeded in the metabolic engineering of tobacco plants by introducing multiple genes as a bacteria-type operon into a plastid genome. The tobacco plastid was transformed with a polycistron consisting of three bacterial genes for the biosynthesis of a biodegradable polyester, polyhydroxybutyrate (PHB). Accumulation of PHB in the leaves of the transgenic tobacco indicated that the introduced genes were polycistronically expressed. This "phyto-fermentation" system can be used in plant production of various chemical commodities and pharmaceuticals.     

Fluorescent antibiotic resistance marker for tracking plastid transformation in higher plants.

Plastid transformation in higher plants is accomplished through a gradual process, during which all the 300-10,000 plastid genome copies are uniformly altered. Antibiotic resistance genes incorporated in the plastid genome facilitate maintenance of transplastomes during this process. Given the high number of plastid genome copies in a cell, transformation unavoidably yields chimeric tissues, which requires the identification of transplastomic cells in order to regenerate plants. In the chimeric tissue, however, antibiotic resistance is not cell autonomous: transplastomic and wild-type sectors both have a resistant phenotype because of phenotypic masking by the transgenic cells. We report a system of marker genes for plastid transformation, termed FLARE-S, which is obtained by translationally fusing aminoglycoside 3"-adenyltransferase with the Aequorea victoria green fluorescent protein. 3"-adenyltransferase (FLARE-S) confers resistance to both spectinomycin and streptomycin. The utility of FLARE-S is shown by tracking segregation of individual transformed and wild-type plastids in tobacco and rice plants after bombardment with FLARE-S vector DNA and selection for spectinomycin and streptomycin resistance, respectively. This method facilitates the extension of plastid transformation to nongreen plastids in embryogenic cells of cereal crops.     

Efficient and Stable Transformation of Lactuca sativa L. cv. Cisco (lettuce) Plastids

Transgenic plastids offer unique advantages in plant biotechnology, including high-level foreign protein expression. However, broad application of plastid genome engineering in biotechnology has been largely hampered by the lack of plastid transformation systems for major crops. Here we describe the development of a plastid transformation system for lettuce, Lactuca sativa L. cv. Cisco. The transforming DNA carries a spectinomycin-resistance gene (aadA) under the control of lettuce chloroplast regulatory expression elements, flanked by two adjacent lettuce plastid genome sequences allowing its targeted insertion between the rbcL and accD genes. On average, we obtained 1 transplastomic lettuce plant per bombardment. We show that lettuce leaf chloroplasts can express transgene-encoded GFP to ~36% of the total soluble protein. All transplastomic T0 plants were fertile and the T1 progeny uniformly showed stability of the transgene in the chloroplast genome. This system will open up new possibilities for the efficient production of edible vaccines, pharmaceuticals, and antibodies in plants.     

Plant plastid engineering

Genetic material in plants is distributed into nucleus, plastids and mitochondria. Plastid has a central role of carrying out photosynthesis in plant cells. Plastid transformation is becoming more popular and an alternative to nuclear gene transformation because of various advantages like high protein levels, the feasibility of expressing multiple proteins from polycistronic mRNAs, and gene containment through the lack of pollen transmission. Recently, much progress in plastid engineering has been made. In addition to model plant tobacco, many transplastomic crop plants have been generated which possess higher resistance to biotic and abiotic stresses and molecular pharming. In this mini review, we will discuss the features of the plastid DNA and advantages of plastid transformation. We will also present some examples of transplastomic plants developed so far through plastid engineering, and the various applications of plastid transformation.     

Precise excision of plastid DNA by the large serine recombinase Bxb1

Marker genes are essential for the selection and identification of rarely occurring transformation events generated in biotechnology. This includes plastid transformation, which requires that multiple copies of the modified chloroplast genome be present to obtain genetically stable transplastomic plants. However, the marker gene becomes dispensable when homoplastomic plants are obtained. Here, we demonstrate the precise excision of attP‐ and attB‐flanked DNA from the plastid genome mediated by the large serine recombinase Bxb1. We transformed the tobacco plastid genome with the pTCH‐PB vector containing a stuffer fragment of DNA flanked by directly oriented nonhomologous attP and attB recombinase recognition sites. In the absence of the Bxb1 recombinase, the transformed plastid genomes were stable and heritable. Nuclear‐transformed transgenic tobacco plants expressing a plastid‐targeted Bxb1 recombinase were crossed with transplastomic pTCH‐PB plants, and the T₁ hybrids exhibited efficient excision of the target sequence. The Bxb1–att system should prove to be a useful tool for site‐specifically manipulating the plastid genome and generating marker‐free transplastomic plants.     

质体基因工程中选择标记基因研究进展

与细胞核基因工程相比,质体基因工程能更安全、精确和高效地对外源基因进行表达,作为下一代转基因技术已广泛用于基础研究和生物技术应用领域。与细胞核基因工程一样,质体基因工程中也需要合适的选择标记基因用于转化子的筛选和同质化,但基于质体基因组的多拷贝性和母系遗传特点,转化子的同质化需要一个长期的筛选过程,这就决定了质体基因工程中选择标记基因的选择标准将不同于细胞核基因工程中广泛使用的现行标准。目前,质体基因工程的遗传转化操作中使用较多的是抗生素选择标记基因,出于安全性考虑,需要找到可替换、安全的选择标记基因或有效的标记基因删除方法。本文在对质体基因工程研究的相关文献分析基础之上,对主要使用的选择标记基因及其删除体系进行了综述,并对比了其优缺点,同时探讨了质体基因工程中所使用的报告基因,以期为现有选择标记基因及其删除体系的改进和开发提供一定参考,进一步推动质体基因工程,尤其是单子叶植物质体基因工程的发展。     

Methylation of chloroplast DNA does not affect viability and maternal inheritance in tobacco and may provide a strategy towards transgene containment

We report the integration of a type II restriction-methylase, mFokI, into the tobacco chloroplast genome and we demonstrate that the introduced enzyme effectively directs the methylation of its target sequence in vivo and does not affect maternal inheritance. We further report the transformation of tobacco with an E. coli dcm methylase targeted to plastids and we demonstrate efficient cytosine methylation of the plastid genome. Both adenosine methylation of FokI sites and cytosine methylation of dcm sites appeared phenotypically neutral. The ability to tolerate such plastid genome methylation is a pre-requisite for a proposed plant transgene containment system. In such a system, a chloroplast located, maternally inherited restriction methylase would provide protection from a nuclear-encoded, plastid targeted restriction endonuclease. As plastids are not paternally inherited in most crop species, pollen from such plants would carry the endonuclease transgene but not the corresponding methylase; the consequence of this should be containment of all nuclear transgenes, as pollination will only be viable in crosses to the appropriate transplastomic maternal background.     

The two largest chloroplast genome-encoded open reading frames of higher plants are essential genes

The chloroplast genomes of most higher plants contain two giant open reading frames designated ycf1 and ycf2. In tobacco, ycf1 potentially specifies a protein of 1901 amino acids. The putative gene product of the ycf2 reading frame is a protein of 2280 amino acids. In an attempt to determine the functions of ycf1 and ycf2, we have constructed several mutant alleles for targeted disruption and/or deletion of these two reading frames. The mutant alleles were introduced into the tobacco plastid genome by biolistic chloroplast transformation to replace the corresponding wild-type alleles by homologous recombination. Chloroplast transformants were obtained for all constructs and tested for their homoplastomic state. We report here that all transformed lines remained heteroplastomic even after repeated cycles of regeneration under high selective pressure. A balanced selection was observed in the presence of the antibiotic spectinomycin, resulting in maintenance of a fairly constant ratio of wild-type versus transformed genome copies. Upon removal of the antibiotic and therewith release of the selective pressure, sorting out towards the wild-type plastid genome occurred in all transplastomic lines. These findings suggest that ycf1 and ycf2 are functional genes and encode products that are essential for cell survival. The two reading frames are thus the first higher plant chloroplast genes identified as being indispensable.     

Targeting a nuclear anthranilate synthase alpha-subunit gene to the tobacco plastid genome results in enhanced tryptophan biosynthesis. Return of a gene to its pre-endosymbiotic origin

Anthranilate synthase (AS), the control enzyme of the tryptophan (Trp) biosynthetic pathway, is encoded by nuclear genes, but is transported into the plastids. A tobacco (Nicotiana tabacum) cDNA (ASA2) encoding a feedback-insensitive tobacco AS alpha-subunit was transformed into two different sites of the tobacco plastid genome through site-specific insertion to obtain transplastomic plants with normal phenotype and fertility. A high and uniform level of ASA2 mRNA was observed in the transplastomic plants but not in the wild type. Although the plants with the transgene insertion at ndhF-trnL only expressed one size of the ASA2 mRNA, the plants with the transgene incorporated into the region between accD and open reading frame (ORF) 184 exhibited two species of mRNA, apparently due to readthrough. The transplastomic plants exhibited a higher level of AS alpha-subunit protein and AS enzyme activity that was less sensitive to Trp-feedback inhibition, leading to greatly increased free Trp levels in leaves and total Trp levels in seeds. Resistance to an AS inhibitor, 5-methyl-Trp, was found during seed germination and in suspension cultures of the transplastomic plants. The resistance to the selection agent spectinomycin and to 5-methyl-Trp was transmitted maternally. These results demonstrate the feasibility of modifying the biosynthetic pathways of important metabolites through transformation of the plastid genome by relocating a native gene from the nucleus to the plastid genome. Very high and uniform levels of gene expression can be observed in different lines, probably due to the identical insertion sites, in contrast to nuclear transformation where random insertions occur.     

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.     

Chloroplast tubules visualized in transplastomic plants expressing green fluorescent protein

A fusion between the plastid psbA promoter and the green fluorescent protein gene (gfp) was introduced into the tobacco chloroplast genome by stable plastid transformation. GFP was synthesized actively and exclusively in the chloroplasts. Tubular projections filled with GFP but containing no chlorophyll were visualized for the first time in chloroplasts of these transplastomic plants. Occasionally, the tubules connect chloroplasts with each other, suggesting the possibility of the exchange of endogenous proteins. However, the fusion of protoplasts between the transplastomic and wild-type plants showed that such chloroplast connections might be rare in mesophyll protoplasts.     

Plastid marker-gene excision by transiently expressed CRE recombinase

We report plastid marker-gene excision with a transiently expressed CRE, site-specific recombinase. This is a novel protocol that enables rapid removal of marker genes from the approximately 10,000 plastid genome copies without transformation of the plant nucleus. Plastid marker excision was tested in tobacco plants transformed with a prototype polycistronic plastid vector, pPRV110L, designed to express multiple genes organized in an operon. The pMHB10 and pMHB11 constructs described here are dicistronic and encode genes for herbicide (bar) and spectinomycin (aadA) resistance. In vector pMHB11, expression of herbicide resistance is dependent on conversion of an ACG codon to an AUG translation initiation codon by mRNA editing, a safety feature that prevents translation of the mRNA in prokaryotes and in the plant nucleus. In the vectors, the marker gene (aadA) is flanked by 34-bp loxP sites for excision by CRE. Marker excision by a transiently expressed CRE involves introduction of CRE in transplastomic leaves by agro-infiltration, followed by plant regeneration. In tobacco transformed with vectors pMHB10 and pMHB11, Southern analysis and PCR identified approximately 10% of the regenerated plants as marker-free.     

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。     

Transgene-induced pleiotropic effects in transplastomic plants

Since the first demonstration of stable transgene integration in the plastid genome (plastome) of higher plants, plastid transformation has been used for a wide range of purposes, including basic studies as well as biotechnological applications, showing that transplastomic plants are an effective system to produce recombinant proteins. Compared to nuclear transformation, the main advantages of this technology are the high and stable production level of proteins as well as the natural containment of transgenes. To date, more than 100 transgenes have been successfully expressed in plant chloroplasts. In some cases, however, unintended pleiotropic effects on plant growth and physiology were shown in transplastomic plants. In this paper, we review such effects and discuss some of the technologies developed to overcome them.     

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.