Abstract
BackgroundGene editing technologies enable the precise insertion of favourable mutations and performance enhancing trait genes into chromosomes whilst excluding all excess DNA from modified genomes. The technology gives rise to a new class of biotech crops which is likely to have widespread applications in agriculture. Despite progress in the nucleus, the seamless insertions of point mutations and non-selectable foreign genes into the organelle genomes of crops have not been described. The chloroplast genome is an attractive target to improve photosynthesis and crop performance. Current chloroplast genome engineering technologies for introducing point mutations into native chloroplast genes leave DNA scars, such as the target sites for recombination enzymes. Seamless editing methods to modify chloroplast genes need to address reversal of site-directed point mutations by template mediated repair with the vast excess of wild type chloroplast genomes that are present early in the transformation process.ResultsUsing tobacco, we developed an efficient two-step method to edit a chloroplast gene by replacing the wild type sequence with a transient intermediate. This was resolved to the final edited gene by recombination between imperfect direct repeats. Six out of 11 transplastomic plants isolated contained the desired intermediate and at the second step this was resolved to the edited chloroplast gene in five of six plants tested. Maintenance of a single base deletion mutation in an imperfect direct repeat of the native chloroplast rbcL gene showed the limited influence of biased repair back to the wild type sequence. The deletion caused a frameshift, which replaced the five C-terminal amino acids of the Rubisco large subunit with 16 alternative residues resulting in a ~30-fold reduction in its accumulation. We monitored the process in vivo by engineering an overlapping gusA gene downstream of the edited rbcL gene. Translational coupling between the overlapping rbcL and gusA genes resulted in relatively high GUS accumulation (~0.5 % of leaf protein).ConclusionsEditing chloroplast genomes using transient imperfect direct repeats provides an efficient method for introducing point mutations into chloroplast genes. Moreover, we describe the first synthetic operon allowing expression of a downstream overlapping gene by translational coupling in chloroplasts. Overlapping genes provide a new mechanism for co-ordinating the translation of foreign proteins in chloroplasts.Electronic supplementary materialThe online version of this article (doi:10.1186/s12870-016-0857-6) contains supplementary material, which is available to authorized users.
Highlights
Gene editing technologies enable the precise insertion of favourable mutations and performance enhancing trait genes into chromosomes whilst excluding all excess DNA from modified genomes
Insertion of a point mutation denoted by an asterisk (*) in the right rbcL sequence duplication creates an imperfect directly repeated sequence (Fig. 1a)
An important set of genes is located in chloroplasts including those essential for photosynthesis such as rbcL
Summary
Gene editing technologies enable the precise insertion of favourable mutations and performance enhancing trait genes into chromosomes whilst excluding all excess DNA from modified genomes. Methods to edit genes based on programmable nucleases have revolutionised the manipulation of nuclear genomes in multicellular eukaryotes [1, 2] They allow precise targeted changes ranging from single nucleotide alterations to the seamless insertion of exogenous genes into nuclear chromosomes [3,4,5]. Whilst programmable nucleases have been imported into mitochondria to induce double strand DNA breaks [11], genome editing requires the additional step of introducing a nucleic acid template into organelles to repair and introduce the desirable changes at the break sites. This requires methods that lead to the isolation of stable organelle transformants. Application of editing technologies to transgenes would allow their seamless insertion into chloroplast DNA to improve photosynthesis [18] and stress tolerance [19] as well as express industrial and health care products in chloroplasts [14, 20,21,22]
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