Identification of cis-elements conferring high levels of gene expression in non-green plastids

Although our knowledge about the mechanisms of gene expression in chloroplasts has increased substantially over the past decades, next to nothing is known about the signals and factors that govern expression of the plastid genome in non-green tissues. Here we report the development of a quantitative method suitable for determining the activity of cis-acting elements for gene expression in non-green plastids. The in vivo assay is based on stable transformation of the plastid genome and the discovery that root length upon seedling growth in the presence of the plastid translational inhibitor kanamycin is directly proportional to the expression strength of the resistance gene nptII in transgenic tobacco plastids. By testing various combinations of promoters and translation initiation signals, we have used this experimental system to identify cis-elements that are highly active in non-green plastids. Surprisingly, heterologous expression elements from maize plastids were significantly more efficient in conferring high expression levels in root plastids than homologous expression elements from tobacco. Our work has established a quantitative method for characterization of gene expression in non-green plastid types, and has led to identification of cis-elements for efficient plastid transgene expression in non-green tissues, which are valuable tools for future transplastomic studies in basic and applied research.     

Extensive homologous recombination between introduced and native regulatory plastid DNA elements in transplastomic plants

Homologous recombination within plastids directs plastid genome transformation for foreign gene expression and study of plastid gene function. Though transgenes are generally efficiently targeted to their desired insertion site, unintended homologous recombination events have been observed during plastid transformation. To understand the nature and abundance of these recombination events, we analyzed transplastomic tobacco lines derived from three different plastid transformation vectors utilizing two different loci for foreign gene insertion. Two unintended recombinant plastid DNA species were formed from each regulatory plastid DNA element included in the transformation vector. Some of these recombinant DNA species accumulated to as much as 10–60% of the amount of the desired integrated transgenic sequence in T0 plants. Some of the recombinant DNA species undergo further, “secondary” recombination events, resulting in an even greater number of recombinant plastid DNA species. The abundance of novel recombinant DNA species was higher in T0 plants than in T1 progeny, indicating that the ancillary recombination events described here may have the greatest impact during selection and regeneration of transformants. A line of transplastomic tobacco was identified containing an antibiotic resistance gene unlinked from the intended transgene insertion as a result of an unintended recombination event, indicating that the homologous recombination events described here may hinder efficient recovery of plastid transformants containing the desired transgene. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Transfer of transformed chloroplasts from Nicotiana tabacum to the Lycium barbarum plants

Plastid transformation is an attractive technology for obtaining crop plants with new useful characteristics and for fundamental researches of plastid functioning and nuclear-plastid interaction. The aim of our experiments was to obtain plants with Lycium barbarum nucleus and transformed Nicotiana tabacum plastids. Plastome of previously engineered transplastomic tobacco plants contains reporter uidA gene and selective aadA gene that confers resistance to antibiotics spectinomycin and streptomycin. Asymmetric somatic hybridization was performed for transferring transformed tobacco plastids from transplastomic tobacco plants into recipient L. barbarum wild type plants. Hybrid L. barbarum plants containing transformed tobacco plastome with active aadA and uidA genes were obtained as a result of the experiments. The work shows the possibility of obtaining transplastomic plants by transferring the transformed plastids to remote species by using somatic hybridization technology. The developed technique is especially effective for obtaining transplastomic plants that have low regeneration and transformation ability.     

Construction of marker-free transplastomic tobacco using the Cre-loxP site-specific recombination system

Incorporation of a selectable marker gene in the plastid genome is essential to uniformly alter the thousands of genome copies in a tobacco cell. When transformation is accomplished, however, the marker gene becomes undesirable. Here we describe plastid transformation vectors, the method of plastid transformation using tobacco leaves and alternative protocols for marker gene excision with the P1 bacteriophage Cre-loxP site-specific recombination system. Plastid vectors carry a marker gene flanked with directly oriented loxP sites and a gene of interest, which are introduced into plastids by the biolistic process. The transforming DNA integrates into the plastid genome by homologous recombination via plastid targeting sequences. Marker gene excision is accomplished by a plastid-targeted Cre protein expressed from a nuclear gene. Expression may be from an integrated gene introduced by Agrobacterium transformation (Transformation Protocol), by pollination (Pollination Protocol) or from a transient, non-integrated T-DNA (Transient Protocol). Transplastomic plants are obtained in about 3 months, yielding seed after 2 months. The time required to remove the plastid marker and nuclear genes and to obtain seed takes 10-16 months, depending on which protocol is used.     

Isolation of precise plastid deletion mutants by homology-based excision: a resource for site-directed mutagenesis, multi-gene changes and high-throughput plastid transformation

We describe a simple and efficient homology-based excision method to delete plastid genes. The procedure allows one or more adjacent plastid genes to be deleted without the retention of a marker gene. We used aad A-based transformation to duplicate a 649 bp region of plastid DNA corresponding to the atp B promoter region. Efficient recombination between atp B repeats deletes the intervening foreign genes and 1984 bp of plastid DNA (co-ordinates 57 424–59 317) containing the rbc L gene. Only five foreign bases are present in Δ rbc L plants illustrating the precision of homology-based excision. Sequence analysis of non-functional rbc L-related sequences in Δ rbc L plants indicated an extra-plastidic origin. Mutant Δ rbc L plants were heterotrophic, pale-green and contained round plastids with reduced amounts of thylakoids. Restoration of autotrophy and leaf pigmentation following aad A-based transformation with the wild-type rbc L gene ruled out mutations in other genes. Excision and re-use of aadA shows that, despite the multiplicity of plastid genomes, homology-based excision ensures complete removal of functional aad A genes. Rescue of the Δ rbc L mutation and autotrophic growth stabilizes transgenic plastids in heteroplasmic transformants following antibiotic withdrawal, enhancing the overall efficiency of plastid transformation. Unlike the available set of homoplasmic knockout mutants in 25 plastid genes, the rbc L deletion mutant isolated here is readily transformed with the efficient aad A marker gene. This improvement in deletion design facilitates advanced studies that require the isolation of double mutants in distant plastid genes and the replacement of the deleted locus with site-directed mutant alleles and is not easily achieved using other methods.     

Removal of antibiotic resistance genes from transgenic tobacco plastids

Removal of antibiotic resistance genes from genetically modified (GM) crops removes the risk of their transfer to the environment or gut microbes. Integration of foreign genes into plastid DNA enhances containment in crops that inherit their plastids maternally. Efficient plastid transformation requires the aadA marker gene, which confers resistance to the antibiotics spectinomycin and streptomycin. We have exploited plastid DNA recombination and cytoplasmic sorting to remove aadA from transplastomic tobacco plants. A 4.9 kbp insert, composed of aadA flanked by bar and uidA genes, was integrated into plastid DNA and selected to remove wild-type plastid genomes. The bar gene confers tolerance to the herbicide glufosinate despite being GC-rich. Excision of aadA and uidA mediated by two 174 bp direct repeats generated aadA-free T(0) transplastomic plants containing the bar gene. Removal of aadA and bar by three 418 bp direct repeats allowed the isolation of marker-free T(2) plants containing a plastid-located uidA reporter gene.     

Modifying fatty acid profiles through a new cytokinin‐based plastid transformation system

The widespread use of herbicides and antibiotics for selection of transgenic plants has not been very successful with regard to commercialization and public acceptance. Hence, alternative selection systems are required. In this study, we describe the use of ipt, the bacterial gene encoding the enzyme isopentenyl transferase from Agrobacterium tumefaciens, as a positive selectable marker for plastid transformation. A comparison between the traditional spectinomycin‐based aadA selection system and the ipt selection system demonstrated that selection of transplastomic plants on medium lacking cytokinin was as effective as selection on medium containing spectinomycin. Proof of principle was demonstrated by transformation of the kasIII gene encoding 3‐ketoacyl acyl carrier protein synthase III into tobacco plastids. Transplastomic tobacco plants were readily obtained using the ipt selection system, and were phenotypically normal despite over‐expression of isopentenyl transferase. Over‐expression of KASIII resulted in a significant increase in 16:0 fatty acid levels, and a significant decrease in the levels of 18:0 and 18:1 fatty acids. Our study demonstrates use of a novel positive plastid transformation system that may be used for selection of transplastomic plants without affecting the expression of transgenes within the integrated vector cassette or the resulting activity of the encoded protein. This system has the potential to be applied to monocots, which are typically not amenable to traditional antibiotic‐based selection systems, and may be used in combination with a negative selectable marker as part of a two‐step selection system to obtain homoplasmic plant lines.     

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.     

Multiple pathways for Cre/lox-mediated recombination in plastids

Plastid transformation technology involves the insertion by homologous recombination and subsequent amplification of plastid transgenes to approximately 10 000 genome copies per leaf cell. Selection of transformed genomes is achieved using a selectable antibiotic resistance marker that has no subsequent role in the transformed line. We report here a feasibility study in the model plant tobacco, to test the heterologous Cre/lox recombination system for antibiotic marker gene removal from plastids. To study its efficiency, a green fluorescent protein reporter gene activation assay was utilized that allowed visual observation of marker excision after delivery of Cre to plastids. Using a combination of in vivo fluorescence activation and molecular assays, we show that transgene excision occurs completely from all plastid genomes early in plant development. Selectable marker-free transplastomic plants are obtained in the first seed generation, indicating a potential application of the Cre/lox system in plastid transformation technology. In addition to the predicted transgene excision event, two alternative pathways of Cre-mediated recombination were also observed. In one alternative pathway, the presence of Cre in plastids stimulated homologous recombination between a 117 bp transgene expression element and its cognate sequence in the plastid genome. The other alternative pathway uncovered a plastid genome 'hot spot' of recombination composed of multiple direct repeats of a 5 bp sequence motif, which recombined with lox independent of sequence homology. Both recombination pathways result in plastid genome deletions. However, the resultant plastid mutations are silent, and their study provides the first insights into tRNA accumulation and trans-splicing events in higher plant plastids.     

Visual marker and Agrobacterium-delivered recombinase enable the manipulation of the plastid genome in greenhouse-grown tobacco plants

Successful manipulation of the plastid genome (ptDNA) has been carried out so far only in tissue-culture cells, a limitation that prevents plastid transformation being applied in major agronomic crops. Our objective is to develop a tissue-culture independent protocol that enables manipulation of plastid genomes directly in plants to yield genetically stable seed progeny. We report that in planta excision of a plastid aurea bar gene (bar(au) ) is detectable in greenhouse-grown plants by restoration of the green pigmentation in tobacco leaves. The P1 phage Cre or PhiC31 phage Int site-specific recombinase was delivered on the Agrobacterium T-DNA injected at the axillary bud site, resulting in the excision of the target-site flanked marker gene. Differentiation of new apical meristems was forced by decapitating the plants above the injection site. The new shoot apex that differentiated at the injection site contained bar(au)-free plastids in 30-40% of the injected plants, of which 7% transmitted the bar(au)-free plastids to the seed progeny. The success of obtaining seed with bar(au)-free plastids depended on repeatedly forcing shoot development from axillary buds, a process that was guided by the size and position of green sectors in the leaves. The success of in planta plastid marker excision proved that manipulation of the plastid genomes is feasible within an intact plant. Extension of the protocol to in planta plastid transformation depends on the development of new protocols for the delivery of transforming DNA encoding visual markers.     

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.     

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.     

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。     

The tobacco plastid accD gene is essential and is required for leaf development

Angiosperm plastid genomes typically encode approximately 80 polypeptides, mainly specifying plastid-localized functions such as photosynthesis and gene expression. Plastid protein synthesis and expression of the plastid clpP1 gene are essential for development in tobacco, indicating the presence of one or more plastid genes whose influence extends beyond the plastid compartment. The plastid accD gene encodes the beta-carboxyl transferase subunit of acetyl-CoA carboxylase and is present in the plastids of most flowering plants, including non-photosynthetic parasitic plants. We replaced the wild-type accD gene with an aadA-disrupted mutant allele using homologous recombination. Persistent heteroplasmy in the presence of antibiotics indicated that the wild-type accD allele was essential. The phenotype of the accD knockout was revealed in plastid transformants grown in the absence of antibiotics. Leaves contained pale green sectors and lacked part or all of the leaf lamina due to arrested division or loss of cells. Abnormal structures were present in plastids found in mutant plants, indicating that accD might be required to maintain the plastid compartment. Loss of the plastid compartment would be expected to be lethal. These results provide genetic evidence showing the essential role of plastid ACCase in the pathway leading to the synthesis of products required for the extra-plastidic processes needed for leaf development.     

Efficient elimination of selectable marker genes from the plastid genome by the CRE-lox site-specific recombination system

Incorporation of a selectable marker gene during transformation is essential to obtain transformed plastids. However, once transformation is accomplished, having the marker gene becomes undesirable. Here we report on adapting the P1 bacteriophage CRE-lox site-specific recombination system for the elimination of marker genes from the plastid genome. The system was tested by the elimination of a negative selectable marker, codA, which is flanked by two directly oriented lox sites (>codA>). Highly efficient elimination of >codA> was triggered by introduction of a nuclear-encoded plastid-targeted CRE by Agrobacterium transformation or via pollen. Excision of >codA> in tissue culture cells was frequently accompanied by a large deletion of a plastid genome segment which includes the tRNA-ValUAC gene. However, the large deletions were absent when cre was introduced by pollination. Thus pollination is our preferred protocol for the introduction of cre. Removal of the >codA> coding region occurred at a dramatic speed, in striking contrast to the slow and gradual build-up of transgenic copies during plastid transformation. The nuclear cre gene could subsequently be removed by segregation in the seed progeny. The modified CRE-lox system described here will be a highly efficient tool to obtain marker-free transplastomic plants.     

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.     

High-frequency transformation of undeveloped plastids in tobacco suspension cells

Although leaf chloroplast transformation technology was developed more than a decade ago, no reports exist of stable transformation of undeveloped plastids or other specialized plastid types, such as proplastids, etioplasts, or amyloplasts. In this work we report development of a dark-grown tobacco suspension cell model system to investigate the transformation potential of undeveloped plastids. Electron microscope analysis confirmed that the suspension cells carry plastids that are significantly smaller (approximately 50-fold less in volume) and have a very different subcellular localization and developmental state than leaf cell chloroplasts. Using antibiotic selection in the light, we demonstrated that both plastid and nuclear transformation of these cell suspensions is efficient and reproducible, with plastid transformation frequency at least equal to that of leaf chloroplast transformation. Homoplasmic plastid transformants are readily obtained in cell colonies, or in regenerated plants, providing a more consistent and versatile model than the leaf transformation system. Because of the uniformity of the cell suspension model, we could further show that growth rate, selection scheme, particle size, and DNA amount influence the frequency of transformation. Our results indicate that the rate-limiting steps for nuclear and plastid transformation are different, and each must be optimized separately. The suspension cell system will be useful as a model for understanding transformation in those plant species that utilize dark-grown embryogenic cultures and for characterizing the steps that lead to homoplasmic plastid transformation.     

Translational fusion of chloroplast-expressed human papillomavirus type 16 L1 capsid protein enhances antigen accumulation in transplastomic tobacco

Human Papillomavirus (HPV) is the causal agent of cervical cancer, one of the most common causes of death for women. The major capsid L1 protein self-assembles in Virus Like Particles (VLPs), which are highly immunogenic and suitable for vaccine production. In this study, a plastid transformation approach was assessed in order to produce a plant-based HPV-16 L1 vaccine. Transplastomic plants were obtained after transformation with vectors carrying a chimeric gene encoding the L1 protein either as the native viral (L1^v gene) or a synthetic sequence optimized for expression in plant plastids (L1^pt gene) under control of plastid expression signals. The L1 mRNA was detected in plastids and the L1 antigen accumulated up to 1.5% total leaf proteins only when vectors included the 5′-UTR and a short N-terminal coding segment (Downstream Box) of a plastid gene. The half-life of the engineered L1 protein, determined by pulse-chase experiments, is at least 8 h. Formation of immunogenic VLPs in chloroplasts was confirmed by capture ELISA assay using antibodies recognizing conformational epitopes and by electron microscopy. Contribution No. 129 from CNR-IGV, Portici.