Abstract
Chloroplasts play a crucial role in sustaining life on earth. The availability of over 800 sequenced chloroplast genomes from a variety of land plants has enhanced our understanding of chloroplast biology, intracellular gene transfer, conservation, diversity, and the genetic basis by which chloroplast transgenes can be engineered to enhance plant agronomic traits or to produce high-value agricultural or biomedical products. In this review, we discuss the impact of chloroplast genome sequences on understanding the origins of economically important cultivated species and changes that have taken place during domestication. We also discuss the potential biotechnological applications of chloroplast genomes.
Electronic supplementary material
The online version of this article (doi:10.1186/s13059-016-1004-2) contains supplementary material, which is available to authorized users.
Introduction
Chloroplasts are active metabolic centers that sustain life on earth by converting solar energy to carbohydrates through the process of photosynthesis and oxygen release. Although photosynthesis is often recognized as the key function of plastids, they also play vital roles in other aspects of plant physiology and development, including the synthesis of amino acids, nucleotides, fatty acids, phytohormones, vitamins and a plethora of metabolites, and the assimilation of sulfur and nitrogen. Metabolites that are synthesized in chloroplasts are important for plant interactions with their environment (responses to heat, drought, salt, light, and so on) and their defense against invading pathogens. So, chloroplasts serve as metabolic centers in cellular reactions to signals and respond via retrograde signaling [1, 2]. The chloroplast genome encodes many key proteins that are involved in photosynthesis and other metabolic processes.
The advent of high-throughput sequencing technologies has facilitated rapid progress in the field of chloroplast genetics and genomics. Since the first chloroplast genome, from tobacco (Nicotiana tabacum), was sequenced in 1986 [3], over 800 complete chloroplast genome sequences have been made available in the National Center for Biotechnology Information (NCBI) organelle genome database, including 300 from crop and tree genomes. Insights gained from complete chloroplast genome sequences have enhanced our understanding of plant biology and diversity; chloroplast genomes have made significant contributions to phylogenetic studies of several plant families and to resolving evolutionary relationships within phylogenetic clades. In addition, chloroplast genome sequences have revealed considerable variation within and between plant species in terms of both sequence and structural variation. This information has been especially valuable for our understanding of the climatic adaptation of economically important crops, facilitating the breeding of closely related species and the identification and conservation of valuable traits [4, 5]. Improved understanding of variation among chloroplast genomes has also allowed the identification of specific examples of chloroplast gene transfer to plant nuclear or mitochondrial genomes, which has shed new light on the relationship between these three genomes in plants.
In addition to improving our understanding of plant biology and evolution, chloroplast genomics research has important translational applications, such as conferring protection against biotic or abiotic stress and the development of vaccines and biopharmaceuticals in edible crop plants. Indeed, the first commercial-scale production of a human blood protein in a Current Good Manufacturing Processes (cGMP) facility was published recently [6]. The lack of conservation of intergenic spacer regions, even among chloroplast genomes of closely related plant species, and the species specificity of regulatory sequences have facilitated the development of highly efficient transformation vectors for the integration and expression of foreign genes in chloroplasts. Because the published literature is rarely cross-referenced, this review highlights the impact of chloroplast genomes on various biotechnology applications. In addition to our enhanced understanding of chloroplast biology, we discuss in depth the roles of chloroplast genome sequences in improving our understanding of intracellular gene transfer, conservation, diversity, and the genetic basis by which chloroplast transgenes are engineered to enhance plant agronomic traits or to produce high-value agricultural or biomedical products. In addition, we discuss the impact of chloroplast genome sequences on increasing our understanding of the origins of economically important cultivated species and changes that occurred during domestication.
Advances in chloroplast genome sequencing technology
One of the important factors in the rapid advancement of the chloroplast genomics field is improvement in sequencing technologies. In studies conducted before the availability of high-throughput methods, isolated chloroplasts were used for the amplification of the entire chloroplast genome by rolling circle amplification [7–12]. An alternative strategy is to screen bacterial artificial chromosome (BAC) or fosmid libraries using chloroplast genome sequences as probes [13–20]; however, these methods are subject to many challenges, including difficulty in constructing good-quality BAC or fosmid libraries, large numbers of PCR reactions, and the possibility of contamination from other organellar DNA [21–32]. The PCR approach is also difficult to apply to species that have no relatives whose chloroplast genomes have been sequenced or those with highly rearranged chloroplast genomes.
The development of next-generation sequencing (NGS) methods provided scientists with faster and cheaper methods to sequence chloroplast genomes. Moore and colleagues [33] first reported using NGS to determine chloroplast genome sequences, in Nandina and Platanus. Although multiple NGS platforms are available for chloroplast genome sequencing [34], Illumina is currently the major NGS platform used for chloroplast genomes [21, 32, 35, 36] because it allows the use of rolling circle amplification products [35, 37]. Investigators can then use bioinformatics platforms to perform de novo assembly without the need for reference genome sequences; from these assemblies it is possible to identify consensus chloroplast genome sequences [32]. A third-generation sequencer, the PacBio system which uses single molecule real-time (SMRT) sequencing, is now widely used in chloroplast genome sequencing [38–43]. Its advantage is long read lengths [44], which facilitate de novo genome assembly, particularly in the four chloroplast junctions between the inverted repeat (IR) and single-copy regions.
The low accuracy (~85 % of the raw data) of the long reads produced by the PacBio platform [45] can be corrected by combining the latest chemistry with a hierarchical genome assembly process algorithm; accuracy rates as high as 99.999 % can be achieved after such post-error corrections [46]. Accuracy can also be increased using Illumina short reads [42]. In a study of Potentilla micrantha, sequencing with the Illumina platform produced seven contigs covering only 90.59 % of the chloroplast genome; by contrast, using the PacBio platform with error correction, the entire genome was successfully assembled in a single contig [39].
Chloroplast genome structure
The chloroplast genomes of land plants have highly conserved structures and organization of content; they comprise a single circular molecule with a quadripartite structure that includes two copies of an IR region that separate large and small single-copy (LSC and SSC) regions (Fig. 1a, b). The chloroplast genome includes 120–130 genes, primarily participating in photosynthesis, transcription, and translation. Recent studies have identified considerable diversity within non-coding intergenic spacer regions, which often include important regulatory sequences [13]. Despite the overall conservation in structure, chloroplast genome size varies between species, ranging from 107 kb (Cathaya argyrophylla) to 218 kb (Pelargonium), and is independent of nuclear genome size (Table 1). Certain lineages of land-plant chloroplast genomes also show significant structural rearrangements, with evidence of the loss of IR regions or entire gene families. Furthermore, there is also evidence for the existence of linear chloroplast genomes, as illustrated in Fig. 1b. The percentage of each form within the cell varies in different reports [47, 48].
Table 1.
Species | Common name | Accession | Genome size (bp) | Uses | Reference(s) |
---|---|---|---|---|---|
Crops | |||||
Acorus gramineus | Sweet flag | NC_026299 | 152849 | Ornamental | [169] |
Agrostis stolonifera | Creeping bent grass | NC_008591 | 136584 | Forage | [8] |
Allium cepa | Onion | NC_024813 | 153538 | Vegetable | [170] |
Ananas comosus | Pineapple | NC_026220 | 159636 | Fruit | [171] |
Anthriscus cerefolium | Chervil | NC_015113 | 154719 | Medicinal | [172] |
Artemisia frigida | Fringed sagewort | NC_020607 | 151076 | Medicinal | [173] |
Atropa belladonna | Belladonna | NC_004561 | 156687 | Medicinal | [174] |
Brassica napus (2)* | Canola | NC_016734 | 152860 | Oil | [175] |
Calanthe triplicata | Black orchid | NC_024544 | 158759 | Flower | [176] |
Cannabis sativa (2) | Marijuana | NC_027223 | 153854 | Fiber | [177] |
Capsicum annuum (2) | Pepper | NC_018552 | 156781 | Vegetable | [178] |
Carica papaya | Papaya | NC_010323 | 160100 | Fruit | [179] |
Catharanthus roseus | Madagascar periwinkle | NC_021423 | 154950 | Flower | [180] |
Cenchrus americanus | Pearl millet | NC_024171 | 140718 | Cereals | [181] |
Cicer arietinum | Chickpea | NC_011163 | 125319 | Vegetable | [7] |
Coix lacryma-jobi | Job's tears | NC_013273 | 140745 | Cereals | [29] |
Colocasia esculenta | Taro | NC_016753 | 162424 | Vegetable | [182] |
Cucumis sativus (3) | Cucumber | NC_007144 | 155293 | Vegetable | [183] |
Curcuma roscoeana | Jewel of Burma | NC_022928 | 159512 | Medicinal | [184] |
Cymbidium tortisepalum (5) | Cymbidium orchid | NC_021431 | 155627 | Flower | [55] |
Cypripedium formosanum (3) | Formosa's lady's slipper | NC_026772 | 178131 | Flower | [32] |
Daucus carota | Carrot | NC_008325 | 155911 | Vegetable | [9] |
Dendrobium catenatum | Dendrobium orchid | NC_024019 | 152221 | Flower | [56] |
Dieffenbachia seguine | Dumbcane | NC_027272 | 163699 | Ornamental | [185] |
Digitaria exilis | White fonio | NC_024176 | 140908 | Cereals | [181] |
Echinochloa oryzicola | Late barnyard grass | NC_024643 | 139891 | Cereals | [186] |
Ephedra equisetina | Ma Huang | NC_011954 | 109518 | Medicinal | [187] |
Erycina pusilla | Mini orchid | NC_018114 | 143164 | Flower | [36] |
Fagopyrum esculentum (2) | Common buckwheat | NC_010776 | 159599 | Cereals | [188] |
Festuca arundinacea (4) | Kentucky fescue | NC_011713 | 136048 | Forage | [189] |
Fragaria vesca (6) | Wild strawberry | NC_015206 | 155691 | Fruit | [190] |
Glycine max (9) | Soybean | NC_007942 | 152218 | Oil | [18] |
Glycyrrhiza glabra | Common liquorice | NC_024038 | 127943 | Medicinal | [74] |
Gossypium barbadense (22) | Sea island cotton | NC_008641 | 160317 | Fiber | [69] |
Guizotia abyssinica | Ramtilla | NC_010601 | 151762 | Bird seed | [191] |
Helianthus annuus (9) | Common sunflower | NC_007977 | 151104 | Oil | [192] |
Heliconia collinsiana | Platanillo | NC_020362 | 161907 | Ornamental | [193] |
Hordeum vulgare | Barley | NC_008590 | 136462 | Cereals | [8] |
Hyoscyamus niger | Henbane | NC_024261 | 155720 | Medicinal | [194] |
Ipomoea batatas | Sweet potato | NC_026703 | 161303 | Vegetable | [195] |
Ipomoea purpurea | Common morning glory | NC_009808 | 162046 | Ornamental | [196] |
Lactuca sativa | Lettuce | NC_007578 | 152765 | Vegetable | [197] |
Lilium superbum | Turk's-cap lily | NC_026787 | 152069 | Flower | [198] |
Lolium multiflorum (2) | Ryegrass | NC_019651 | 135175 | Lawn | [199] |
Lotus japonicus | Birdsfoot trefoil | NC_002694 | 150519 | Forage | [200] |
Manihot esculenta | Cassava | EU117376 | 161453 | Starch crop | [20] |
Masdevallia picturata (2) | Masdevallia orchid | NC_026777 | 157423 | Flower | [32] |
Musa textilis | Banana | NC_022926 | 161347 | Fruit | [184] |
Nicotiana tabacum (4) | Tobacco | Z00044 | 155943 | Tobacco | [3] |
Nuphar advena | Spatterdock | NC_008788 | 160866 | Medicinal | [201] |
Nymphaea alba (2) | White water-lily | NC_006050 | 159930 | Flower | [24] |
Oncidium hybrid | Oncidium | NC_014056 | 146484 | Flower | [54] |
Oryza sativa (6) | Rice | X15901 | 134525 | Cereals | [202] |
Panax ginseng (2) | Ginseng | NC_006290 | 156318 | Medicinal | [203] |
Panicum virgatum | Switchgrass | NC_015990 | 139619 | Biofuel | [204] |
Paphiopedilum armeniacum (2) | Slipper orchid | NC_026779 | 162682 | Flower | [32] |
Parthenium argentatum | Guayule | NC_013553 | 152803 | Biofuel | [205] |
Pelargonium (2) | Geranium | NC_008454 | 217942 | Flower | [206] |
Phalaenopsis hybrid (3) | Phalaenopsis orchid | NC_007499 | 148964 | Flower | [51] |
Phaseolus vulgaris | Kidney bean | NC_009259 | 150285 | Bean | [78] |
Pisum sativum | Pea | NC_014057 | 122169 | Vegetable | [76] |
Raphanus sativus | Radish | NC_024469 | 153368 | Vegetable | [207] |
Ravenala madagascariensis | Traveller's tree | NC_022927 | 166170 | Ornamental | [184] |
Ricinus communis | Castor bean | NC_016736 | 163161 | Oil | [208] |
Saccharum hybrid (2) | Sugarcane | NC_005878 | 141182 | Sugar | [209] |
Salvia miltiorrhiza | Redroot sage | NC_020431 | 151328 | Medicinal | [210] |
Secale cereale | Rye | NC_021761 | 114843 | Cereals | [64] |
Sesamum indicum | Sesame | NC_016433 | 153324 | Oil | [211] |
Solanum lycopersicum (11) | Tomato | NC_007898 | 155461 | Vegetable | [13] |
Solanum tuberosum | Potato | DQ231562 | 155312 | Starch crop | [212] |
Sorghum bicolor (2) | Sorghum | NC_008602 | 140754 | Cereals | [8] |
Spinacia oleracea | Spinach | NC_002202 | 150725 | Vegetable | [213] |
Trifolium grandiflorum (8) | Large-flower hop clover | NC_024034 | 125628 | Forage | [74] |
Triticum aestivum (6) | Bread wheat | NC_002762 | 134545 | Cereals | [63] |
Vanilla planifolia | Vanilla | NC_026778 | 148011 | Fruit | [32] |
Vigna radiata (3) | Mung bean | NC_013843 | 151271 | Bean | [79] |
Zea mays | Maize | NC_001666 | 140384 | Cereals | [62] |
Zingiber spectabile | True ginger | NC_020363 | 155890 | Ornamental | [193] |
Trees and perennial plants | |||||
Abies koreana | Fir | NC_026892 | 121373 | Wood | [214] |
Actinidia chinensis (2) | Kiwifriut | NC_026690 | 156346 | Fruit | [215] |
Amentotaxus formosana | Taiwan catkin yew | NC_024945 | 136430 | Timber | [216] |
Araucaria heterophylla | Norfolk island araucaria | NC_026450 | 146723 | Timber | [217] |
Bambusa multiplex (4) | Golden goddess bamboo | NC_024668 | 139394 | Ornamental | [91] |
Bambusa oldhamii | Green bamboo | NC_012927 | 139350 | Vegetable | [28] |
Berberis bealei | Beale's mahonia | NC_022457 | 164792 | Ornamental | [218] |
Bismarckia nobilis | Bismarck palm | NC_020366 | 158210 | Ornamental | [193] |
Buxus microphylla | Japanese box | NC_009599 | 159010 | Ornamental | [219] |
Calocedrus formosana | Taiwan incense-cedar | NC_023121 | 127311 | Timber | [220] |
Calycanthus floridus | Carolina-allspice | NC_004993 | 153337 | Medicinal | [23] |
Camellia oleifera (13) | Tea oil plant | NC_023084 | 156971 | Oil | [221] |
Camellia reticulata | To-tsubaki | NC_024663 | 156971 | Flower | [222] |
Carludovica palmata | Toquilla palm | NC_026786 | 158545 | Fiber | [198] |
Castanea mollissima | Chestnut | NC_014674 | 160799 | Fruit | [14] |
Cathaya argyrophylla | Cathaya | NC_014589 | 107122 | Timber | [223] |
Cedrus deodara | Cedar | NC_014575 | 119299 | Timber | [223] |
Cephalotaxus wilsoniana (2) | Wilson plum yew | NC_016063 | 136196 | Timber | [224] |
Chrysobalanus icaco | Coco plum | NC_024061 | 162775 | Fruit | [225] |
Citrus sinensis (2) | Orange | NC_008334 | 160129 | Fruit | [12] |
Cocos nucifera | Coconut | NC_022417 | 154731 | Oil | [226] |
Coffea arabica | Coffee | NC_008535 | 155189 | Beverage | [10] |
Corymbia gummifera (4) | Red bloodwood | NC_022407 | 160713 | Timber | [227] |
Corynocarpus laevigata | Karaka nut | NC_014807 | 159202 | Fruit | [37] |
Cryptomeria japonica | Sugi | NC_010548 | 131810 | Timber | [228] |
Dendrocalamus latiflorus | Sweet giant bamboo | NC_013088 | 139394 | Vegetable | [28] |
Elaeis guineensis | African oil palm | NC_017602 | 156973 | Oil | [229] |
Eucalyptus globulus (32) | Eucalyptus | NC_008115 | 160286 | Timber | [230] |
Hevea brasiliensis | Rubber tree | NC_015308 | 161191 | Rubber | [231] |
Jasminum nudiflorum | Winter jasmine | NC_008407 | 165121 | Ornamental | [232] |
Jatropha curcas | Barbados nut | NC_012224 | 163856 | Biofuel | [233] |
Juniperus bermudiana (4) | Bermuda juniper | NC_024021 | 127659 | Timber | [234] |
Larix decidua | European larch | NC_016058 | 122474 | Timber | [224] |
Licania sprucei (3) | Licania | NC_024065 | 162228 | Ornamental | [225] |
Liquidambar formosana | Chinese sweetgum | NC_023092 | 160410 | Timber | [30] |
Liriodendron tulipifera | Tulip tree | NC_008326 | 159886 | Timber | [235] |
Metasequoia glyptostroboides | Dawn redwood | NC_027423 | 131887 | Timber | [236] |
Millettia pinnata | Indian beech | NC_016708 | 152968 | Ornamental | [81] |
Morus indica (3) | White mulberry | NC_008359 | 158484 | White mulberry | [237] |
Nageia nagi | Asian bayberry | NC_023120 | 133722 | Timber | [220] |
Nandina domestica | Heavenly bamboo | NC_008336 | 156599 | Ornamental | [33] |
Nerium oleander | Oleander | NC_025656 | 154903 | Ornamental | [238] |
Olea europaea (5) | Olive | NC_015604 | 155862 | Oil | [239] |
Phoenix dactylifera | Date palm | NC_013991 | 158462 | Fruit | [240] |
Phyllostachys edulis (4) | Moso bamboo | NC_015817 | 139679 | Timber | [89] |
Picea sitchensis (3) | Sitka spruce | NC_011152 | 120176 | Timber | [35] |
Pinus taiwanensis (12) | Taiwan red pine | NC_027415 | 119741 | Timber | [241] |
Platanus occidentalis | American sycamore | NC_008335 | 161791 | Ornamental | [33] |
Podocarpus lambertii (3) | Podocarpus | NC_023805 | 133734 | Ornamental | [242] |
Populus alba | White poplar | NC_008235 | 156505 | Timber | [243] |
Prinsepia utilis | Himalayan cherry | NC_021455 | 156328 | Ornamental | [244] |
Prunus persica (6) | Peach | NC_014697 | 157790 | Fruit | [14] |
Pseudophoenix vinifera | Florida cherry palm | NC_020364 | 157829 | Ornamental | [193] |
Pseudotsuga sinensis | Chinese douglas | NC_016064 | 122513 | Timber | [224] |
Pyrus pyrifolia (2) | Chinese pear | NC_015996 | 159922 | Fruit | [245] |
Quercus rubra (4) | Oak | NC_020152 | 161304 | Timber | [246] |
Sapindus mukorossi | Soapberries | NC_025554 | 160481 | Medicinal | [247] |
Taiwania cryptomerioides (2) | Taiwania | NC_016065 | 132588 | Timber | [224] |
Theobroma cacao | Cacao tree | HQ336404 | 160604 | Beverage | [14] |
Vaccinium macrocarpon | Large cranberry | NC_019616 | 176045 | Fruit | [248] |
Vitis vinifera | Wine grape | NC_007957 | 160928 | Fruit | [19] |
Wollemia nobilis | Wollemia | NC_027235 | 145630 | Timber | [249] |
*The number of species in the same genus as the listed species that have sequenced and annotated chloroplast genomes is shown in parentheses
Like the genes, the introns in land-plant chloroplast genomes are generally conserved, but the loss of introns within protein-coding genes has been reported in several plant species [49], including barley (Hordeum vulgare) [8], bamboo (Bambusa sp.) [28], cassava (Manihot esculenta) [20], and chickpea (Cicer arietinum) [7]. The proteins encoded by genes in which intron loss is known to occur have diverse functions; they include an ATP synthase (atpF), a Clp protease (clpP), an RNA polymerase (rpoC2), and ribosomal proteins (rpl2, rps12, and rps16) [49]. The majority of reported intron losses have been observed in specific plant groups or species, although some examples of intron loss (such as that in clpP) occur in diverse plant species, including monocots (Poaceae), eudicots (Onagraceae and Oleaceae) and gymnosperms (Pinus) [49].
Diversity of chloroplast genome sequences
At higher taxonomic levels (family level), protein-coding regions and conserved sequences of the chloroplast genome can be used for phylogenetic analysis and domestication studies [49]. Earlier phylogenetic analyses utilized partial chloroplast DNA sequences. The use of variable regions or multiple DNA fragments dramatically enhanced the utility of these analyses but there is insufficient information in these sequences to provide the high-resolution necessary to differentiate closely related taxa, particularly some within-species taxa whose taxonomic relationships are unclear. Complete chloroplast genome sequences are valuable for deciphering phylogenetic relationships between closely related taxa and for improving our understanding of the evolution of plant species.
In this section, we discuss several examples of comparisons of chloroplast genomes, within and between crop species, that have provided unique insight into evolutionary relationships among taxa. We also discuss the origin and geographic distribution of economically important species, as well as their adaptations to different climatic conditions and the use of genome information in their breeding and conservation.
A key application of the chloroplast genome in agriculture is the identification of commercial cultivars and the determination of their purity. DNA barcodes derived from the chloroplast genome can be used to identify varieties and in the conservation of breeding resources. Success in breeding is determined by genetic compatibility and chloroplast genomes serve as a valuable tool for identifying plants that are likely to be closely related and, therefore, genetically compatible. Understanding the genetic relationships between cultivated crops and their wild relatives informs efforts to introduce specific advantageous traits into cultivated crops. In the section below, we discuss how chloroplast genomes have been used to elucidate the evolutionary relationships and domestication history of a few major crops and how this informs breeding programs.
Breeding
The Orchidaceae is a large family that encompasses about 6–11 % of all angiosperms [50] and is important in floriculture. Many commercially important orchid species belong to the subfamily Epidendroideae and chloroplast genomes of several species from this subfamily have been sequenced [51–58]. Because it is easy to perform inter-generic crossing in orchids and because the record of breeding is sometimes incomplete, it is often difficult to validate the parental origin of commercially important varieties [54]. Corrected parental information is important for breeding and variety identification. In an investigation of the Oncidiinae, a subtribe within the Epidendroideae, PCR products derived from eight conserved regions in 15 commercial varieties resolved their phylogenetic relationship at the species level [54] and helped to resolve putative errors in parental origin. Parental records had indicated that Odontoglossum ‘Violetta von Holm’, Odontoglossum ‘Margarete Holm’ and Odontocidium ‘Golden Gate’ are derived from the same female parent (Odontoglossum bictoniense) but phylogenetic analyses of ‘Violetta von Holm’ did not correlate with those of ‘Golden Gate’ or ‘Margarete Holm’ [54]. A possible reason for inconsistencies between the chloroplast DNA-based phylogenetic tree and the parental record is chloroplast capture. Chloroplast capture is the introgression of chloroplasts from one species into another after intrageneric and intergeneric hybridization [59]. Although chloroplast genomes provide useful information for phylogenetic analyses involving closely related taxa, chloroplast capture by hybridization may distort phylogenetic relationships if captured chloroplast genomes or genes included therein are used [60]. The use of both nuclear and chloroplast genomes can provide more complete phylogenies [4, 61].
Phylogenetic studies
There are several published chloroplast genomes from cereals, including those from sorghum (Sorghum bicolor), barley [8], maize (Zea mays) [62], wheat (Triticum aestivum) [63], rye (Secale cereale) [64], and rice (Oryza sativa) [65]. Rice is one of the world's most important crops and is the primary carbohydrate source for the global human population (http://www.ers.usda.gov/topics/crops/rice.aspx). The Oryza species are classified into ten genome types, including six diploids (AA, BB, CC, EE, FF, and GG) and four allotetraploids (BBCC, CCDD, HHJJ, and HHKK). Attempts to clarify the evolutionary relationships between cultivated rice and its wild relatives remain contentious and inconclusive [4]. For example, there are two wild species that have an AA genome in Australia, Oryza meridionalis (annual) and Oryza rufipogon (perennial). Oryza sativa was domesticated from Asian O. rufipogon 10,000 years ago [65]. Nevertheless, analysis of complete Australian and Asian wild rice chloroplast genomes indicated that Australian O. rufipogon chloroplast genomes are more similar to those of Australian O. meridionalis than to those of Asian O. rufipogon [65–67]. Using 19 chloroplast genomes of Oryza AA genome species, a robust phylogenetic tree was established, which will aid in improving rice crops and in conservation strategies [4, 5].
Cotton is the most important textile fiber crop and the first cotton (Gossypium hirsutum) chloroplast genome was published in 2006 [11]. The diploid Gossypium species comprise eight genome groups (A to G and K genomes). Gossypium hirsutum (upland cotton), the most widely planted cotton species in the world, is an allotetraploid of the ancestral A and D genome species [68]. Chloroplast genome sequences are available for 22 Gossypium species and these can be used to glean information about the evolution and domestication of this crop [11, 68, 69] (Table 1). Simple sequence repeat primers were used to investigate 41 species of Gossypium, including all eight genome groups and allotetraploid species [70]. The results indicated that two modern A-genome species, Gossypium herbaceum and Gossypium arboretum, were not cytoplasmic donors of tetraploid (AD) species; instead, the AD genome species originated from an extinct ancestor species of the modern A genome [68, 70].
Domestication
Information on chloroplast genomes is useful for understanding the domestication of several crops, particularly legumes [71]. The chloroplast genome structure of legumes is very interesting; it contains multiple rearrangements, including large inverted segments and loss of inverted repeats [72]. An example is a 51-kb inversion that was first identified in the soybean (Glycine max) chloroplast genome sequence [18] before being reported in most members of the subfamily Papilionoideae [7, 73–77]. A 78-kb reversion was subsequently confirmed in Phaseolus and Vigna chloroplast genomes [78, 79]. More recently, 36-kb [80] and 5.6-kb [81] inversions inside the 51-kb inversion were identified. There are many important genes within these inverted regions but no gene is disturbed and plant survival and performance are not affected. These unique characteristics are not only very useful in phylogenetic studies [82] but also provide important information for chloroplast transformation in legumes. Chloroplast structure is also important for the design of primers needed in the amplification of sequences for further domestication and phylogenetic analysis.
Citrus is one of the most commercially important fruit genera. In 2006, the first Citrus chloroplast genome, that of sweet orange (Citrus × sinensis), was published [12] and this served as a reference genome for subsequent publications [83, 84]. Phylogenetic analysis of 34 chloroplast genomes of Citrus (28) and Citrus-related genera (6) indicated that citrus fruits have the same common ancestor [84, 85]. In four genes (matK, ndhF, ycf1, and ccsA), single-nucleotide variations and insertion/deletion frequencies were clearly higher than average and showed that these genes have been positively selected. The matK gene encodes a maturase that is involved in splicing type II introns and the matK sequence is often used in phylogenetic and evolutionary studies [84]. Positive selection of matK is observed not only in citrus but is common in several other plant species. In fact, more than 30 plant groups have been shown to undergo positive selection of matK genes, indicating that the gene is subject to a number of different ecological selective pressures [86]. The ndhF gene encodes a subunit of the chloroplast NAD(P)H dehydrogenase (NDH) complex. Chloroplast NDH monomers are sensitive to high light stress, suggesting that the ndh genes may also be involved in stress acclimation [87]. These studies indicated that matK and ndhF show positive selection in Australian species, potentially contributing to their adaptation to a hot, dry climate [84, 85].
Bamboo is an economically and ecologically important forest plant in Asia [88]. Bamboo grows quickly and new culms are regenerated from the rhizome after harvesting, making it a sustainable and ecologically and environmentally friendly crop. The first two bamboo chloroplast genomes have been published [28] and many more bamboo chloroplast genomes are now available [88–93]. Bamboo has a long juvenility and it is difficult to obtain flowers for taxonomic studies; consequently the taxonomic relationships of bamboo have proven challenging to unravel on the basis of traditional reproductive organ morphology. Furthermore, the extremely low rate of sequence divergence meant that the taxonomic and phylogenetic relationships of temperate woody bamboos at lower taxonomic levels proved difficult to resolve [88]. These relationships were eventually resolved with high-resolution phylogenetic trees using 25 bamboo chloroplast genomes [93]. In addition to woody bamboos, chloroplast genomes have also been published for herbaceous bamboo [88, 92]. An interesting phenomenon identified in herbaceous bamboo chloroplast genomes is that of gene transfer from the mitochondrial genome to the chloroplast genome. This was an unusual observation, as the chloroplast genome is thought to be nearly immune to the transfer of DNA from nuclear and mitochondrial genomes [88, 92, 94]. A possible reason for this recalcitrance to DNA transfer is the lack of an efficient DNA uptake system [94]. Prior to its observation in herbaceous bamboo, this phenomenon was only observed in two eudicot chloroplast genomes [94] and in monocots [88, 92].
Transfer of chloroplast genes to nuclear or mitochondrial genomes
There are three distinct genomes in plant cells: nuclear, mitochondrial, and plastid. Mitochondria are believed to have evolved from a single endosymbiotic event by the uptake of a proteobacterium, whereas chloroplasts evolved from endosymbiosis of a cyanobacterium, after which there was a massive transfer of genes from the chloroplast to the nucleus [95]. There are distinct translation systems in these organelles: nuclear-encoded genes are translated in the cytosol and the protein products are then transported to the locations in which they function, including chloroplasts [96], whereas chloroplast-encoded proteins are directly synthesized within the chloroplast. Multi-subunit functional protein complexes that are involved in photosynthesis or protein synthesis are also assembled within chloroplasts.
Gene content, number, and structure are conserved in the chloroplast genome sequences of most autotrophic land plants [97, 98] but some protein-encoding genes are absent in specific species [49]. The loss of genes such as infA, rpl22, and ndh from the chloroplast genome and their intracellular transfer to the nuclear or mitochondrial genomes provide valuable information for phylogenetic analyses and evolutionary studies. It is very easy to identify the chloroplast origin of genes in plant mitochondrial or nuclear genomes [99, 100] by intracellular gene transfer [32], but this could also lead to erroneous phylogenic relationships when short sequences are used instead of complete chloroplast genome sequences.
The chloroplast translation initiation factor 1 (infA) is a homolog of the essential gene infA in Escherichia coli [101, 102]. This gene initiates translation in collaboration with two nuclear-encoded initiation factors to mediate interactions between mRNA, ribosomes, and initiator tRNA-Met [102]. Many parallel losses of chloroplast-encoded infA have occurred during angiosperm evolution [102] (Fig. 2). Nuclear-encoded infA genes have been identified in Arabidopsis thaliana, soybean, tomato (Solanum lycopersicum), and ice plant (Mesembryanthemum crystallinum) [102]. Protein sequences of nuclear-encoded infA in these four species contain chloroplast transit peptides. Studies using soybean and A. thaliana infA-GFP proteins have shown that nuclear-encoded infA genes are translated in the cytosol and transported into chloroplasts [102]. Many more chloroplast-encoded infA deletions have been identified recently (Fig. 2).
There are 57 chloroplast genomes in 26 genera in which the essential gene rpl22 is reported to have been deleted from the chloroplast and transferred to the nuclear genome (Fig. 2) [14, 103]. Nuclear-encoded rpl22 contains a transit peptide that is predicted to deliver this protein from the cytosol to chloroplasts. These peptides are diverse, suggesting that there were two independent rpl22 transfers in the Fabaceae and the Fagaceae [14]. Similar transfer to the nucleus has also been observed for rpl32 deletion from chloroplast genomes [104–106].
Eleven chloroplast genes encode ndh subunits, which are involved in photosynthesis. The ndh proteins assemble into the photosystem I complex to mediate cyclic electron transport in chloroplasts [107, 108] and facilitate chlororespiration [109]. Some autotrophic plants lack functional ndh genes in their chloroplast genomes [36, 51, 54, 55, 110–115] (Fig. 2). Unlike the single gene losses described previously, the entire family of ndh genes has been deleted in these plants. Seven orchid chloroplast genomes indicated at least three independent ndh deletions [32]. Some orchid ndh DNA fragments were identified in the mitochondrial genome but the complete ndh genes required to translate putative functional protein complexes are absent [32]. In the nuclear genome of Norway spruce, only non-functional plastid ndh gene fragments are present [116]. Normal photosynthesis is observed in these ndh-deleted species [32, 117]. Furthermore, ndh-deleted transformants are autotrophic and produce carbohydrates through photosynthesis [107, 118–121].
Many more chloroplast-gene deletions have been observed, including deletions of accD, ycf1, ycf2, ycf4, psaI, rpoA, rpl20, rpl23, rpl33, and rps16; many unique gene deletions have been identified in only one or a few species (psbJ, rps2, rps14, and rps19) (Fig. 2). The functions of these genes, phenotypes of their knock-out mutants, and evidence for their transfer are summarized in Additional file 1. Most essential genes that have been lost from chloroplast genomes have been transferred to the nucleus to maintain the plant's photosynthetic capacity, with the exception of ycf1 and ycf2.
In summary, chloroplast genome sequences are most valuable for understanding plant evolution and phylogeny. Databases of not only plant genomes but also plant transcriptomes will be useful in investigating deletion events or the transfer of chloroplast genes to other organellar genomes to complement such deletions.
Advances in chloroplast genome engineering
In the past century, desirable agronomic traits, including yield enhancement and resistance to pathogens or abiotic stress, were achieved by breeding cultivated crops with their wild relatives. As explained above, chloroplast genome sequences are very useful in the identification of closely related, breeding-compatible plant species. With the advent of modern biotechnology, desirable traits from unrelated species can now be readily introduced into commercial cultivars. Such genetically modified crops have revolutionized agriculture in the past two decades, dramatically reducing the use of chemical pesticides and herbicides while enhancing yield. For most commercial cultivars, herbicide- or insect-resistance genes are introduced into the nuclear genome. There are, however, a few limitations for nuclear transgenic plants, including low levels of expression (<1 % total soluble protein (TSP)) and potential escape of transgenes via pollen.
Engineering the introduction of foreign genes into the chloroplast genome addresses both of these concerns. Just two copies of transgenes are typically introduced into the nuclear genome, whereas up to 10,000 transgene copies have been engineered into the chloroplast genome of each plant cell, resulting in extremely high levels of foreign gene expression (>70 % TSP) [122]. Most importantly, chloroplast genomes are maternally inherited in most cultivated crops, minimizing or eliminating transgene escape via pollen [123].
The basic process of chloroplast engineering is explained in Fig. 3a, b. Chloroplast genome engineering is accomplished by integrating foreign genes into intergenic spacer regions without disrupting the native chloroplast genes (Fig. 3a). Two chloroplast genes are used as flanking sequences to facilitate integration of transgene cassettes. Transgene cassettes include a selectable marker gene and gene(s) of interest, both regulated by chloroplast gene promoters and untranslated regions (UTRs; Fig. 3a). Chloroplast genome sequences are essential to build transgene cassettes because they provide both flanking and regulatory sequences. Transgene cassettes that are inserted into bacterial plasmids are called chloroplast vectors and they are bombarded into plant cells using gold particles and a gene gun (Fig. 3b). Because of the presence of chloroplast DNA in the nuclear or mitochondrial genome, transgene cassettes may integrate via homologous or non-homologous recombination events; but any transgenes that are integrated within the nuclear or mitochondrial genome will not be expressed because chloroplast regulatory sequences are not functional in other genomes. If such integration occurs, the transgenes could be easily identified by evaluation of their integration site and eliminated [124].
One of the challenges of creating chloroplast transgenic (transplastomic) plants is the elimination of all untransformed copies (>10,000 per cell) of the native chloroplast genome and replacing them with transformed genomes that contain integrated transgene cassettes. The absence of the native chloroplast genome and the presence of only the modified genomes is referred to as the homoplasmic state, which is typically achieved after two or three rounds of selection (Fig. 3b). The most effective selectable marker used is the aadA gene, which confers resistance to streptomycin and spectinomycin. These antibiotics bind specifically to chloroplast ribosomes and disrupt protein synthesis without interfering with any other cellular process. Efforts to transform the chloroplast genome of cereal crops have been mostly unsuccessful. This could be due to the instability of chloroplast DNA in the mature leaves of cereals [47] or to a requirement for better selectable markers [125].
Table 2 provides the first global, comprehensive summary of the power of chloroplast genetic engineering, utilizing valuable information generated by the sequencing of chloroplast genomes described in previous sections. This table includes the most complete list of chloroplast genomes that have been engineered for enhanced agronomic traits or the production of different bio-products, including biopolymers, industrial enzymes, biopharmaceuticals, and vaccines. Within Table 2, transgenes are grouped according to their functions and are organized according to their site of integration. The efficiency of transgene expression is also included in Table 2, providing important information about the regulatory sequences used to express the transgenes.
Table 2.
Site of integration | Transgenes | Regulatory sequences | Efficiency of expression | Engineered traits or products | Reference(s) |
---|---|---|---|---|---|
Insect or pathogen tolerance | |||||
trnI/trnA | Bgl-1 | 5′psbA/3′psbA | >160-fold enzyme | Resistance against whitefly and aphid | [141] |
trnI/trnA | Pta | 5′psbA/3′psbA | 7.1–9.2 % TSP | Broad-spectrum resistance against aphid, whitefly, Lepidopteran insects, bacterial and viral pathogens | [142] |
trnI/trnA | PelB1, PelD2 | 5′psbA/3′psbA | ~2.42 units mg−1 FW | Resistance against Erwinia soft rot | [150] |
trnI/trnA | RC1011, PG12 | 5′psbA/3′ | 17–38 % TSP | Resistance to Erwinia soft rot and tobacco mosaic virus | [140] |
trnI/trnA | cpo | Prrn/psbA/psbA | NR | Resistance to fungal pathogens in vitro (Aspergillus flavus, Fusarium verticillioides, and Verticillium dahliae) and in planta (Alternaria alternata) | [251] |
trnI/trnA | Bt cry2Aa2 operon | Prrn/ggagg/psbA | 45.3 % TSP | 100 % mortality of cotton bollworm, beet armyworm; cuboidal Bt crystals formation | [137] |
trnI/trnA | Bt cry9Aa2 | Prrn/ggagg/rbcL | ~10 % of TSP | Resistance to Phthorimaea operculella | [252] |
trnI/trnA | msi-99 | Prrn/ggagg/psbA | 21–43 % TSP | Resistance to in planta challenge of Pseudomonas syringae, Aspergillus flavus, Fusarium moniliforme, Verticillium dahlia, and Colletotrichum destructivum | [253] |
trnI/trnA | sporamin1, CeCPI2, and chitinase2 | Prrn/TpsbA | 0.85–1 % TSP | Resistance against Spodoptera litura and Spodoptera exigua leaf spot, as well as soft rot diseases | [254] |
trnI/trnA | MSI-99 | Prrn/Trps16 | 89.75 μg g−1 FW | Resistance against rice blast fungus | [255] |
trnV/rps12/7 | cry1A(c) | Prrn/rbcL/rps16 | 3–5 % of TSP | Resistance to larvae of Heliothis virescens, Helicoverpa zea, and Spodoptera exigua | [256] |
trnV/rps12/7 | cry1Ab | Prrn/T7gene10/rbcL | NR | Resistance to caterpillar of Anticarsia gemmatalis | [145] |
rbcL/accD | cry2Aa2 | Prrn/ggagg/psbA | 2–3 % of TSP | Resistance to Heliothis virescens, Helicoverpa zea, and Spodoptera exigua | [257] |
Abiotic stress tolerance | |||||
trnI/trnA | tps1 | Prrn/ggagg/psbA | >169-fold transcript | Drought tolerance: growth in 6 % polyethylene glycol and rehydration after 24 days of drought | [258] |
trnI/trnA | merA/merB | Prrn/ggagg/psbA | NR | Phytoremediation: high level tolerance to the organomercurial compounds, up to 400 μM phenylmercuric acetate | [259] |
trnI/trnA | badh | Prrn/T7 g10/rps16 | 93–101 μM g−1 FW | Salt tolerance: carrot plants survived up to 400 mM NaCl | [135] |
trnI/trnA | γ-TMT | Prrn/T7g 10/TpsbA | >7.7 % TSP | Increased salt and heavy metal tolerance, enhanced accumulation of ɑ-tocopherol in seeds | [153] |
trnI/trnA | mt1 | Prrn/T7 g10/Trps16 | NR | Phytoremediation: resistant to mercury, up to 20 μm | [260] |
trnV/rps12/7 | b-bar1 | Prrn/TrbcL | >7 % TSP | Resistance to the herbicide phosphinothricin | [261] |
trnV/rps7/12 | EPSPS | Prrn/Trps16 | >10 % TSP | Resistance to the herbicide glyphosate | [262] |
rbcL/accD | EPSPS/aroA | Prrn/ggagg/psbA | NR | Resistance to glyphosate (>5 mM) | [129] |
rbcL/accD | mALS | PpsbA/TpsbA | NR | Tolerant to pyrimidinylcarboxylate, imidazolinon, and sulfonylurea/pyrimidinylcarboxylate herbicides | [263] |
rbcL/accD | Bar | Prrn/rbcL/psbA | NR | Herbicide resistance: up to 25 μg ml−1 glufosinate | [264] |
rbcL/rbcL | Hppd | psbA/psbA/3′rbcL | 5 % TSP | Resistance to herbicide | [265] |
rbcL/accD | panD | Prrn/rbcL 3′ | >4-fold β-alanine | Tolerance to high-temperature stress | [266] |
trnfM/trnG | lycopene β-cyclase | atpI/rps16 | 0.28 mg g−1 DW | Herbicide resistance and triggers conversion of lycopene | [133] |
prs14/trnG | HTP, TCY, TMT | Prrn/T7 g10/TrbcL | NR | Increase in vitamin E in fruit; cold-stress tolerance | [267] |
Other agronomic traits | |||||
trnI/trnA | phaA | Prrn/psbA/psbA | 14.71β-ketothiolase mg−1 FW | Engineered cytoplasmic male sterility | [268] |
trnI/trnA | RbcS | T7g10 or psbA | >150-fold RbcS transcript | Restoration of RuBisCO activity in rbcS mutants | [136] |
rbcL/accD | TC, γ -TMT | PpsbA/Trsp16 | 3 nmol h−1 mg−1 FW | Vitamin E accumulation in tobacco and lettuce | [269] |
rbcL/accD | CrtZ, CrtW | Prrn/Trps16 | NR | Accumulation of astaxanthin fatty acid esters in lettuce | [270] |
trnV/orf708 | BicA | psbA/psbA/psbA | ~0.1 % TSP | CO2 capture within leaf chloroplasts | [271] |
trnV/3′rps12 | Trx f, Trx m | prrn T7G10/rps12 | NR | Starch synthesis/chloroplast redox regulation | [272] |
trnfM/trnG | CV-N | Prrn/T7g10/TatpA | ~0.3 % TSP | Increased mRNA stability and protein stability with the expression of CV-N in chloroplasts | [273] |
trnI/trnA | Bgl-1 | 5′psbA/3′psbA | 44.4 units Bgl1 g−1 FW | β-Glucosidase increased enzyme cocktail efficiently to release sugar from paper, citrus peel, and wood | [141] |
trnI/trnA | ubiC | 5′psbA/3′psbA | 25 % DW | 250-fold higher pHBA polymer accumulation than nuclear transgenic lines | [149] |
trnI/trnA | man 1 | 5′psbA/3′psbA | 25 units g−1 FW | Mannanase increased enzyme cocktail released sugar from paper, citrus peel, and wood | [274] |
trnI/trnA | cutinase or swoIlenin | 5′PsbA/3′PsbA | 47.7 % reduction of MGDG and DGDG in cutinase and 68.5 % in swollenin | Swollenin enlarged and irreversibly unwound cotton fiber; cutinase showed esterase and lipase activity; used in enzyme cocktails | [275] |
trnI/trnA | bgl1 | 5′psbA/3′psbA | 14 units mg−1 FW | Enzyme cocktails produced glucose from filter paper, pine wood, or citrus peel | [150] |
swo1 | NR | ||||
xyn2 | 421 units mg−1 FW | ||||
Acetyl sylan esterase | NR | ||||
celD | 493 units mg−1 FW | ||||
celO | 442 units mg−1 FW | ||||
Lipase | NR | ||||
Cutinase | 15 units mg−1 FW | ||||
trnI/trnA | PMK, MVK, MDD, AACT, HMGS, HMGRt; IPP, FPP, ADS, CYP71AV1, AACPR | Prrn/PpsbA | 0.1 mg g−1 FW | Artemisinic acid for several isoprenoid products | [276] |
trnI/trnA | Cel6A,Cel6B | Prrn/rbcL/rbcL | 2–4 % TSP | Hydrolyzed crystalline cellulose | [277] |
trnfM/trnG | bgl1C, cel6B, cel9A, xeg74 | Prrn/T7g10/TrbcL | 5– 40 % TSP | Cell wall-degrading enzyme activity | [278] |
rbcL/accD | phbC, phbA, phbB | Prrn/rbcL 3′ | 0.16 % DW | Polyhydroxybutyrate (PHB) accumulation in leaves | [279] |
rbcL/accD | crtZ, crtW | Prrn/Trps16 | >0.5 % DW | Astaxanthin accumulation | [280] |
trnV/rps7 | EGPh | psbA/psbA/Trps16 | 25 % TSP | Chloroplast-derived β-1,4-endoglucanase (EGPh) was recovered from dry leaves and digested carboxymethyl cellulose (CMC) substrate | [281] |
trnI/trn A | EX4 | PpsbA/TpsbA | 14.3 % TSP | CTB–EX4 showed increased insulin secretion similar to the commercial injectable EX4 in pancreatic β-cells and in mice fed with cells expressing EX4 in chloroplasts | [160] |
trnI/trn A | MBP | PpsbA/TpsbA | 2 % TSP | Amyloid loads were reduced in ex vivo studies in human Alzheimer’s brain and in vivo in Alzheimer’s mice fed with bio-encapsulated CTB–MBP. Abeta was also reduced in retinae and loss of retinal ganglion cells was prevented | [162] |
trnI/trn A | FVIII | PpsbA/TpsbA | 370 mg g−1 FW | Feeding of the HC/C2 antigen mixture substantially suppressed T-helper cell responses and inhibitor formation against FVIII in hemophilia A mice | [282] |
trnI/trn A | HSA | PpsbA/TpsbA | 26 % TSP | In vitro chaperone activity of Trx m and Trx f | [283] |
trnI/trn A | EDA | PpsbA/TpsbA | 2.0 % TSP | The vaccine adjuvant EDA from fibronectin retains its proinflammatory properties when expressed in tobacco chloroplasts | [284] |
trnI/trn A | Proinsulin | PpsbA/TpsbA | 47 % TSP in tobacco, 53 % TLP in lettuce | Oral delivery of proinsulin in plant cells lowered glucose levels comparably to injectable commercial insulin | [285] |
trnI/trn A | HSA | psbA/psbA/psbA | ~11 % TSP | First report of human blood protein in chloroplasts; function not evaluated | [286] |
trnI/trn A | IGF | psbA/psbA/psbA | 32.7 % TSP | Promoted growth of cultured HU-3 cells in a dose-dependent manner | [287] |
trnI/trnA | FIX | PpsbA/TpsbA | 1 mg g−1 DW (0.56 % TLP) | Oral delivery of CTB-FIX lettuce cells suppressed inhibitor formation against FIX in hemophilia B mice | [6] |
trnI/trnA | FIX | Ppsba/TpsbA | 3.8 % TSP; 0.4 mg g−1 FW | Tolerance induction via complex immune regulation, involving tolerogenic dendritic and T-cell subsets | [288] |
trnI/trnA | GAA | Ppsba/TpsbA | 5.7 mg g−1 DW | Reduced toxic antibody responses in enzyme replacement therapy in Pompe mice | [289] |
trnI/trnA |
ACE2
Ang-(1–7) |
PpsbA/TpsbA | CTB–ACE2: 2.14 % TLP CTB-Ang1–7: 8.7 % TLP |
Oral delivery of ACE2 and Ang (1–7) significantly improved cardiopulmonary structure and functions, decreased the elevated right ventricular systolic blood pressure and improved pulmonary blood flow in animals with induced pulmonary hypertension | [161] |
trnI/trn A | BACE | Prrn/TpsbA | 2.0 % TSP | Immunogenic response against the BACE antigen in mice | [290] |
trnI/trn A | IFNα2b | Prrn/TpsbA | 3 mg g−1 FW | Protected cells against VSV CPE and HIV; increased MHC I antibody on splenocytes and total number of natural killer cells and protected mice from a highly metastatic lung tumor | [291] |
trnI/trn A | CTB-pins | Prrn/T7g10/TpsbA and rps16 | 16 % TSP in tobacco, 72 % TLP in lettuce | CTB-proinsulin-fed non-obese diabetic mice significantly decreased inflammation (insulitis); insulin-producing β cells in pancreatic islets were highly protected, increased in insulin production with lower blood or urine glucose levels; increased expression of immunosuppressive cytokines | [128, 292] |
rbcL/accD | IFN-γ | PpsbA/TpsbA | 6 % TSP | Protection of human lung carcinoma cells against infection by encephalomyocarditis virus | [293] |
rbcL/accD | hTrx | PpsbA/Trps16 | 1 % TSP | Protected mouse from hydrogen peroxide | [294] |
rbcL/accD | A1AT | PpsbA/TrbcL | 2 % TSP | Binds to porcine pancreatic elastase | [295] |
rbcL/accD | TGFβ3 | Prrn/T7g10/psbC | 12 % TLP | Inhibits mink lung epithelial cell proliferation | [296] |
trnV/3′rps12 | hCT-1 | Prrn/G10L/Trps16 | 5 % TSP | Biologically active on human hepatocarcinoma cell line | [297] |
trnV/rps7/12 | hST | PpsbA or Prrn/G10L/Trps16 | 0.2–7.0 % TSP | Promotes growth of Nb2 cells in a dose-dependent manner | [298] |
trnfM/trnG | pal, cpl-1 | Prrn/T7g10/TpsbA | ~30 % TSP | Bacteriolytic activity and kills Streptococcus pneumoniae, the causative agent of pneumonia | [299] |
trnI/trn A | ESAT-6 | 5′psbA/3′psbA | ~7.5 % TSP | Hemolysis of red blood cells and GM1 binding | [165] |
trnI/trn A | AMA1 | 5′psbA/3′psbA | 7.3 % TSP in tobacco, 13.2 % TSP in lettuce | Long-term immunity against cholera challenge; inhibition of malarial parasite; protection correlated with IgA and IgG1 | [164] |
trnI/trn A | MSP1 | 5′psbA/3′psbA | 10.1 % TSP in tobacco, 6.1 % TSP in lettuce | ||
trnI/trn A | 2 L21 | 5′psbA/3′psbA | 6.0 % TSP | ||
trnI/trn A | Pag | 5′psb/3′psbA | ~29.6 % TSP | Macrophage lysis assay, systemic immune response, toxin neutralization assay, mice survived (100 %) challenge with lethal doses of anthrax toxin | [300, 301] |
trnI/trn A | L1 | PpsbA/TpsbA | 20–26 % TSP | Induced systemic immune response and produced neutralizing antibodies in mice | [302] |
trnI/trnA | RA4 | PpsbA/T psbA | 0.2 % TLP | Oral administration elicited both mucosal and systemic Th1/Th2 responses to reduce Toxoplasma parasite load | [303] |
trnI/trnA | rFaeG | PpsbA/TrbcL | >1 % DW | Transplastomic plants expressing the rFaeG protein could possibly be used for delivery of an oral vaccine against porcine F4+ ETEC infections | [304] |
trnI/trn A | F1-V | Prrn/TpsbA | 14.8 % TSP | Orally immunized mice heavily challenged with plague (Yersinia pestis) were protected better than those given IP injections | [305] |
trnI/trn A | CTB-2 L21 | PpsbA/TpsbA | 31.1 % TSP | Immunogenic in mice following IP or oral administration | [306] |
trnI/trnA | VP8* | psbA/psbA/Trps16 | 600 μg g−1 FW | Induced strong immune response and virus neutralization | [307] |
trnI/trn A | CtxB | Prrn/ggagg/TpsbA | 4.1 % TSP | Efficient GM1 ganglioside-binding | [308] |
trnI/trn A | LTB | Prrn/ggagg/TpsbA | 2.5 % TSP | GM1 ganglioside-binding assay | [309] |
trnI/trn A | LecA | Prrn/T7g10/TpsbA | 7 % TSP | Systemic immune response in mice | [310] |
trnI/trn A | BACE | Prrn/TpsbA | 2.0 % TSP | Immunogenic response against the BACE antigen in mice | [290] |
rbcL/accD | OspA, OspA-T | PpsbA/TpsbA | 1–10 % TSP | Systemic immune response and protection against Borrelia burgdorferi (Lyme disease) | [311] |
trnN/trn R | LTB | Prrn/T7g10/TrbcL | 2.3 % TSP | GM1 ganglioside-binding assay; oral immunization partially protected mice from cholera toxin challenge | [312] |
trnN/trnR | DPT | Prrn/T7g10/TrbcL | 0.8 % TSP | Immunogenic in orally inoculated mice with freeze-dried chloroplast-derived multi-epitope DPT protein | [313] |
trnN/trnR | C4V3 | Prrn/T7g10/TrbcL | ~15 μg mg−1 DW | Plant-derived C4V3 has elicited both systemic and mucosal antibody responses in mice, as well as CD4+ T cell proliferation responses | [314] |
trnN/trnR | L1 | Prrn/TrbcL | >2 % of TSP | Proper folding and display of conformational epitopes for L1 in the fusion protein by antigen capture ELISA | [315] |
trnfM/trnG | p24 | Prrn/T7g10/TrbcL | ~4 % TSP | Induced strong CD4+ and CD8+ T-cell responses in mice | [316] |
trnGtrnfM | HEV E2 | Prrn/psbA/TpsbA | 1.09 ng μg−1 TSP | Immune response in mice against hepatitis E virus | [317] |
trnH/trnK | CSFV E2 | Prrn/TpsbA | 1–2 % TSP | Immune response in mice against swine fever | [318] |
rrn16/rps12/7 | TetC | Prrn/T7 g10/TrbcL atpB/TrbcL |
10–25 % TSP | Mice developed systemic immune response and survived the tetanus toxin challenge | [319] |
rrn16/trnI | E7 | PpsbA/Trps | 3–8 % TSP | Several therapeutic HPV-specific E7-based vaccine formulations have been tested in animal models and some have advanced into clinical trials | [320] |
Abbreviations: Ang (1–7) Angiotensin (1–7), BACE human b-site APP cleaving enzyme, Bgl β-glucosidase, CPE carbapenemase-producing Enterobacteriaceae, CTB cholera toxin B subunit, DGDG digalactosyldiacylglycerol, DPT diphteria, pertussis, tetanus, DW dry weight, EDA extra domain A-fibronectin, ELISA enzyme-linked immunosorbent assay, ETEC enterotoxigenic Escherichia coli, EX4 exendin-4, FVIII coagulation factor VIII, FW fresh weight, HPV human papilloma virus, IP intraperitoneal, MBP myelin basic protein, MGDG monogalactosyldiacylglycerol, NR not recorded, RbcS small subunit of RuBisCO, RuBisCO ribulose-1,5-bisphosphate carboxylase/oxygenase, TLP total leaf protein, TSP total soluble protein, VSV vesicular stomatitis virus
Impact of sequence diversity in the chloroplast genome on transgene integration
Figure 3a shows examples of transplastomic genomes that have been transformed with either an endogenous or a heterologous flanking sequence. Every single nucleotide change in the heterologous sequence was subsequently edited out and corrected to achieve 100 % homology to the native sequence within the intergenic spacer region (Fig. 3a). The repetitive editing process significantly reduces the efficiency of transgene integration when using heterologous flanking sequences. This challenge is made even more difficult by inadequate conservation of intergenic spacer regions, even within the same family. Figure 3c shows comparisons of 21 of the most variable intergenic spacer regions; only four of the >150 spacer regions, including the trnl/trnA spacer region, are conserved among members of the Solanaceae. Among grass chloroplast genomes, not a single intergenic spacer region is conserved [8]. This necessitates construction of species-specific chloroplast vectors using endogenous flanking sequences and underscores the need to sequence the chloroplast genomes of economically important crop species.
Ideal sites in the chloroplast genome for transgene integration
The selection of a suitable intergenic spacer region from among more than 100 sites found in each chloroplast genome is a major concern. Statements on the lack of positional effects in the transplastomic literature are common and are used to contrast chloroplast genetic engineering with nuclear transgene integration, which is often associated with profound differences in the expression of transgenes dependent on their site of integration. Evidence shows, however, that there are also positional effects within the chloroplast genome (Table 2). IR regions are found in duplicate in most chloroplast genomes; therefore, transgenes should be inserted within the IR region instead of the SSC or LSC regions because this should double the copy number of transgenes. Integration of a transgene cassette into one copy of the IR facilitates integration into the other copy, thereby enhancing selection pressure to achieve homoplasmy through this copy correction mechanism, a characteristic feature of the chloroplast genome [126–128]. Therefore, the site of integration plays a crucial role in transgene expression level and in enhancing homoplasmy under selection by antibiotics. Most importantly, in all sequenced chloroplast genomes within a single plant species, the DNA sequence in one copy of the IR is identical to that in the other copy, without any exception (Table 1).
An early controversy in the chloroplast genetic engineering field was the suitability of transcriptionally silent spacer regions, where native genes (for example, rbcL/accD) are located on opposite strands of the chloroplast genome, or transcriptionally active spacer regions, where native genes (for example, trnA/trnI) are located within operons on the same strand. After a herbicide resistance gene was introduced into the transcriptionally active spacer region for the first time [129], most subsequent studies preferentially used this site of integration (Table 2). The integration of transgenes into the transcriptionally active spacer region (trnl/trnA) has led to 25-fold higher expression of transgenes compared with the transcriptionally silent spacer region (rbcl/accD) [130], possibly due to the presence of multiple promoters (heterologous and endogenous) that enhance transcription. Introns present within trnI/trnA genes (used as flanking sequences) also provide efficient processing of native or foreign transcripts. The trnA gene intron includes a chloroplast origin of replication and produces more copies of the template (chloroplast vectors) for integration of the transgene cassette [131]. In fact, among 114 transgenes in different plant species in Table 2, 71 are integrated at the trnA/trnI site of the chloroplast genome, confirming the unique advantages of this site [127, 129, 130].
Role of chloroplast genome regulatory sequences in transgene expression
In addition to the site of integration, regulatory sequences located upstream (promoter, 5′ UTR) and downstream (3′ UTR) of transgenes play a major role in determining their expression level. The psbA regulatory region, first used almost 25 years ago [131], still appears to be the best option for use in an expression cassette, as the psbA gene encodes the most highly translated protein in the chloroplast [132] and it can also mediate light-induced activation of translation [128]. Indeed, almost all highly expressed transgenes (>70 % TSP, >25 % dry weight) utilize the psbA regulatory region; among 114 transgenes expressed via the chloroplast genome, 84 use the psbA regulatory sequence (Table 2). Other endogenous regulatory sequences that are used include rbcL and atpA, which result in lower transgene expression levels than the psbA promoter/5′ UTR.
Using regulatory regions from photosynthetic genes has the advantage of light regulation, making them ideal for transgene expression in photosynthetic organs (leaves; Fig. 3d, e). However, when the lettuce psbA regulatory region was used in tobacco chloroplasts or vice versa, transgene expression was dramatically reduced (Fig. 3d, e) [128]. Nucleotide differences within the psbA 5′ UTR between tobacco and lettuce (Lactuca sativa) resulted in changes that decreased the interaction of RNA-binding proteins and produced variation in the size of the stem, bulge, and terminal loop of the UTR [128]. In addition, most regulatory proteins (including sigma factors that bind to the promoter region) are nuclear encoded and transported to chloroplasts. This underscores a caveat associated with using regulatory sequences for transgene expression: the need to make species-specific chloroplast vectors to accommodate highly specific regulatory region-binding proteins.
Heterologous regulatory sequences are necessary for transgene expression that is independent of cellular control, especially in non-photosynthetic organs such as fruits and edible roots, where chloroplast protein synthesis is poor [133]. A heterologous UTR (T7 gene10) was first evaluated for expression in leaves [127, 134] and was subsequently tested in non-green tissues. When the expression of BETAINE ALDEHYDE DEHYDROGENASE (BADH) was regulated by the T7 gene10 UTR in carrot (Daucus carota) plants, 75 % of the expression level in leaves was observed in non-green edible roots, conferring the highest level of salt tolerance (400 mM NaCl) found in the published literature (Fig. 4i, j) [135]. Although T7 gene10 has been successfully used to engineer salt tolerance in non-green tissues, its expression level is not as high as that of the psbA regulatory sequence in leaves [136]. The only other heterologous UTR that expressed transgenes at high levels is that from the Bacillus thuringiensis (Bt) operon [137]. Use of this operon produced the highest level of insecticidal toxin protein (52 % TLP) ever reported in the published literature [137]. These high levels of toxin accumulation in chloroplasts could result from the combination of high-level expression and protein stability; the Bt protein formed cuboidal crystals within chloroplasts (Fig. 4e) due to co-expression of a chaperone that facilitates folding. When fed, transplastomic leaves, cotton bollworm (Helicoverpa sp.) were killed with a single bite of leaf and insects that had 40,000-fold increased resistance to Bt were also killed (Fig. 4f, g). Nevertheless, expression of this transgene in tomato fruit is very poor [133, 138, 139] and further research is needed to enhance transgene expression in fruits.
Engineering the chloroplast genomes for biotechnology applications
Conferring stress tolerance
In the past decade, chloroplast genetic engineering has focused primarily on the overexpression of target genes with the potential to enhance biotic stress tolerance, which is very important for plant protection and yield enhancement. Yield loss due to insect pests can be very serious in many countries. In addition to cotton bollworm resistance conferred by hyper-expression of Bt protein in chloroplasts [137], there are many other striking recent examples of improved biotic stress tolerance. Retrocyclin-101 and Protegrin-1 protect against Erwinia soft rot and tobacco mosaic virus (TMV), which result in yield loss in several cultivated crops [140]. Whitefly and aphid resistance has been accomplished by expressing β-glucosidase [141], which releases insecticidal sugar esters from hormone conjugates. Multiple resistances against aphids, whiteflies, lepidopteran insects, and bacterial and viral pathogens were achieved by expressing the Pinellia ternata agglutinin (PTA) gene in the chloroplast genome [142]. More than 40 transgenes have been stably integrated into and expressed within the chloroplast genome, conferring important agronomic traits, including insect resistance in edible crops cabbage (Brassica oleracea) [143], soybean [144, 145], and eggplant (Solanum melongena) [146].
More recently, scientists have begun to explore new strategies to downregulate specific target genes. One such approach is to express double-stranded RNAs (dsRNAs) within the chloroplast genome and to use RNA interference (RNAi) to confer the desired agronomic traits, mainly resistance to insects that cause severe yield loss. This strategy has been demonstrated by expressing long or short dsRNAs that activate RNAi and disrupt target genes in insects, providing efficient protection against insects without the need for chemical pesticides. One such example is the suppression of three essential proteins required for insect survival—lepidopteran chitin synthase (Chi), cytochrome P450 monooxygenase (P450), and V-ATPase—using dsRNAs in the tobacco chloroplast system [147]. Each dsRNA was expressed independently in chloroplasts and leaves were fed to insects. The transcription level of target genes in Helicoverpa insects decreased to almost undetectable levels in the midgut, resulting in a significant reduction in the net weight of larvae and in pupation rate [147]. Transplastomic potato plants producing β-actin-targeting long dsRNA were lethal to Colorado potato beetle (Leptinotarsa decemlineata) larvae, providing yet another crop protection mechanism [148].
Synthesis of enzymes and biomaterials
In addition to improved resistance against both biotic and abiotic stress, the chloroplast genome has been engineered to produce useful enzymes, biomaterials, and biofuels, or even to enhance biomass. The first report of metabolic engineering using chloroplast genomes produced the highest level of the poly(p-hydroxybenzoic acid (pHBA) polymer (25 % dry weight) in normal healthy plants despite the diversion of a major metabolic intermediate [149]. The first use of plant-derived enzyme cocktails for the production of fermentable sugars from lignocellulosic biomass was accomplished recently [150]. Unlike the single biofuel enzymes previously expressed in chloroplasts, nine different genes from bacteria or fungi were expressed in E. coli or tobacco chloroplasts using a new technique that enabled the insertion of fungal genes with several introns, eliminating the need to prepare cDNA libraries. Industrial fermentation systems are currently limited by high cost and low production capacity; chloroplast-derived enzyme cocktails offer several striking advantages, including significantly reduced cost, improved stability of chloroplast-derived enzymes, and no need for enzyme purification. Interestingly, expression of β-glucosidase released hormones from conjugates, resulting in elevated phytohormone levels and increased biomass [141], an unexpected outcome of enzyme expression.
Enhancing nutrition
Seed oils, such as those from soybean, rapeseed (Brassica napus), and maize, are the major dietary source of vitamin E. They have very low α-tocopherol content but relatively high levels of γ-tocopherol. Only a few seed oils, such as sunflower (Helianthus annuus) seed oil, contain high levels of α-tocopherol, an important precursor of vitamin E [151]. γ-Tocopherol is the biosynthetic precursor of α-tocopherol, suggesting that the α-tocopherol biosynthetic pathway catalyzed by γ-tocopherol methyl transferase (γ-TMT) is the rate-limiting step [152]. Engineering of the γ-tmt gene into the chloroplast genome resulted in the formation of multiple layers of the inner chloroplast envelope (Fig. 4h) due to γ-TMT overexpression, with around tenfold higher conversion of γ-tocopherol to α-tocopherol in seeds [153]. Likewise, introducing lycopene β-cyclase genes into the tomato plastid genome increased the conversion of lycopene into provitamin A (β-carotene), with obvious phenotypic changes (Fig. 4k) [154].
Biopharmaceuticals
At present, protein drugs are extremely expensive; for example, >90 % of the global population cannot afford insulin, a drug needed to treat the global diabetes epidemic. The high cost of protein drugs is due to their production in prohibitively expensive fermentation systems (which cost more than $450–700 million to build depending on their capacity [155, 156]), prohibitively expensive purification from host proteins, the need for refrigerated storage and transport, and the short shelf-life of the final product. Protein drugs made by plant chloroplasts overcome most of these challenges because they do not require expensive fermentation systems and are produced in federal drug administration (FDA)-approved hydroponic greenhouses (Fig. 4a) [157]. Lettuce leaves expressing protein drugs are lyophilized and stored indefinitely at ambient temperature without losing their efficacy (Fig. 4b–d) [6]. The plant cell wall protects protein drugs from acids and enzymes in the stomach because human enzymes do not digest plant cell wall glycans. Human gut microbes, however, have evolved to break down every glycosidic bond in the plant cell wall and therefore release the protein drug into the gut lumen, directing its delivery to the blood or immune system [158, 159].
Oral delivery of several human therapeutic proteins expressed in chloroplasts is highly efficacious in the treatment of several human diseases, including diabetes, cardiovascular disease, pulmonary hypertension, and Alzheimer’s disease. Most proteins were expressed in tobacco chloroplasts for initial evaluation and were subsequently expressed in lettuce chloroplasts for advancing them to the clinic. Oral delivery of exendin-4, which modulates the secretion of insulin in a glucose-dependent manner, lowered glucose in diabetic animals by stimulating the production of insulin in a manner similar to that of the injectable drug [160]. Oral delivery of angiotensin-converting enzyme 2 (ACE2) and angiotensin (Ang) (1–7) significantly improved cardiopulmonary structure and function, decreased elevated right ventricular systolic blood pressure, and improved pulmonary blood flow in animals with induced pulmonary hypertension [161]. Oral delivery of plant cells expressing ACE2 and Ang (1–7) also reduced endotoxin-induced uveitis (EIU) and dramatically decreased cellular infiltration and retinal vasculitis, as well as damage and folding in experimental autoimmune uveoretinitis [158]. It is also possible to orally deliver protein drugs across the blood–brain barrier to the Alzheimer’s brain to remove plaques [162].
The first industrial-scale production of human blood clotting factor in a cGMP facility was reported recently [6] (Fig. 4a–d). In a 1000 ft2 hydroponic cGMP facility, it is possible to produce up to 30,000 doses for a 20-kg pediatric patient. Clotting factor made in lettuce was stable for up to 2 years when lyophilized cells were stored at ambient temperature, completely eliminating the need for the cold chain. This enables the first commercial development of an oral drug and addresses the extremely expensive purification, cold storage and transportation, and short shelf-life of current protein drugs. Oral delivery of a broad dose range was effective in the prevention of antibody formation after injection of clotting factor IX (FIX), further facilitating human clinical studies.
Vaccines against infectious diseases
The current iteration of vaccines, using attenuated bacteria or viruses, offer protection against major infectious diseases but they also present major challenges. For example, the oral polio vaccine that is used around the globe has caused severe polio resulting from mutations and recombination with other viruses [163]. In addition, all current vaccines require cold storage and transportation, making distribution in developing countries a major challenge. Many of these challenges can be overcome by using chloroplasts.
One successful chloroplast-derived vaccine conferred dual immunity against cholera and malaria in animal studies [164]. Cholera is a major disease causing high mortality, with the only licensed vaccine being not only expensive but also limited in its duration of protection. No vaccine is currently available for malaria. The cholera toxin-B subunit (CTB) of Vibrio cholerae was fused to the malarial vaccine antigen apical membrane antigen-1 (AMA1) and merozoite surface protein-1 (MSP1) and expressed in lettuce or tobacco chloroplasts. While no suitable models exist to test human malaria, a cholera toxin challenge using mice immunized with chloroplast-expressed CTB was highly effective and provided the longest duration of protection in the published literature [164]. These early results show that chloroplasts are ideal for producing low-cost booster vaccines against several infectious diseases [165] for which the global population has been primed previously (Table 2), but lack of an oral priming strategy is still a major limitation in this field.
Moving forward
It is amazing that the chloroplast genome can express >120 foreign genes from different organisms, including bacteria, viruses, fungi, animals, and humans. The insertion of commercially useful traits, including herbicide and insect resistance, into soybean resulted in high-level expression and superior transgene containment, with no antibiotic selectable markers; but even so, these lines were not developed commercially. Nevertheless, recurring concerns about insect resistance against biopesticides have resulted in new USDA requirements on planting Bt corn [122], which may eventually require utilization of the transplastomic approach to confer agronomic traits. The nuclear transgenic approach is inadequate to develop products when higher-level transgene expression is a requirement. Thus, chloroplast transformation has a unique advantage in advancing the field of molecular farming for the production of vaccines, biopharmaceuticals, or other bio-products.
Although products with high-level expression have now advanced to the clinic or are in commercial development, a better understanding of chloroplast translation is required to improve several other gene products. The availability of chloroplast genome sequences should help in the development of codon optimization programs using highly expressed chloroplast genes, but among the ~3000 cultivated crops, sequenced chloroplast genomes are available for crops from fewer than 70 genera. Major funding agencies have not supported crop chloroplast genome sequence projects because of the misconception that all chloroplast genomes are similar, as evidenced by the publication of fewer than ten crop chloroplast genome sequences between 1986 and 2004. This review illustrates the importance of sequencing more crop chloroplast genomes for various biotechnology applications. Furthermore, new selectable markers are needed to transform the chloroplast genomes of cereals, which has been elusive for the past two decades.
Chloroplast genome sequences will be valuable assets in herbal medicine. Most medicinal plants are rare species and very little information is available to confirm their identity. DNA barcodes derived from chloroplast genomes will be useful for identifying varieties and resources; this concept is also valuable in the identification of the origin of cultivated crops and their close relatives to enhance breeding or transfer of useful traits. Molecular techniques to sequence the genomes of single chloroplasts could help to eliminate chloroplast-like sequences that are present in the mitochondrial or nuclear genome. The ability to sequence chloroplast genomes using minimal leaf materials could help us to understand variations in different segments of a variegated leaf in horticultural crops. Further, determining complete chloroplast genome sequences from fossils or recently extinct plants could shed more light on chloroplast genome evolution; help us to understand these species’ inadequate fitness to cope with environmental changes; and help us to build new phylogenetic trees. The technology for isolating DNA from fossils is already available [166–168]. All of these goals can be accomplished with less expensive and more accurate genome sequences, utilizing longer read sequencing technology and new bioinformatics tools.
Abbreviations
ACE2, Angiotensin-converting enzyme 2; BAC, bacterial artificial chromosome; Bt, Bacillus thuringiensis; CTB, Cholera toxin B subunit; cGMP, Current Good Manufacturing Processes; CTB, Cholera toxin B subunit; dsRNA, double-stranded RNA; FIX, clotting factor IX; infA, translation initiation factor 1; IR, inverted repeat; LSC, large single copy; ndh, NAD(P)H dehydrogenase; NCBI, National Center for Biotechnology Information; NGS, next-generation sequencing; RNAi, RNA interference; SSC, small single copy; γ-TMT, γ-Tocopherol methyltransferase; TSP, total soluble protein; UTR, untranslated region; Ang (1–7), Angiotensin (1–7)
Acknowledgements
We acknowledge valuable contributions from editors of Genome Biology (Drs Dominique Morneau and Ripudaman Bains) to enhance the flow and presentation to non-specialists and reviewers for their critical comments.
Funding
Research from the Daniell Laboratory included in this review was supported by the Bill and Melinda Gates Foundation (OPP1031406), the National Institutes of Health (NIH; R01 HL107904, HL109442, GM 63879, EY 024564), Novo Nordisk, Bayer, and Department of Energy ARPA-E grants to Henry Daniell.
Authors’ contributions
HD and CSL wrote this review. MY assembled Table 2 and Figs. 3 and 4 with guidance from HD. WJC assembled Table 1 and Figs. 1 and 2 with guidance from CSL. All authors read and approved the final manuscript.
Competing interests
Henry Daniell, as a pioneer in the field of chloroplast genetic engineering, has several patents in this field but has no financial conflict of interest to declare. A complete list of published patents is available at the Google Scholar weblink: http://scholar.google.com/citations?user=7sow4jwAAAAJ&hl=en
Additional file
References
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