Abstract
Gene-editing techniques are currently revolutionizing biology, allowing far greater precision than previous mutagenic and transgenic approaches. They are becoming applicable to a wide range of plant species and biological processes. Gene editing can rapidly improve a range of crop traits, including disease resistance, abiotic stress tolerance, yield, nutritional quality and additional consumer traits. Unlike transgenic approaches, however, it is not facile to forensically detect gene-editing events at the molecular level, as no foreign DNA exists in the elite line. These limitations in molecular detection approaches are likely to focus more attention on the products generated from the technology than on the process in itself. Rapid advances in sequencing and genome assembly increasingly facilitate genome sequencing as a means of characterizing new varieties generated by gene-editing techniques. Nevertheless, subtle edits such as single base changes or small deletions may be difficult to distinguish from normal variation within a genotype. Given these emerging scenarios, downstream 'omics' technologies reflective of edited affects, such as metabolomics, need to be used in a more prominent manner to fully assess compositional changes in novel foodstuffs. To achieve this goal, metabolomics or 'non-targeted metabolite analysis' needs to make significant advances to deliver greater representation across the metabolome. With the emergence of new edited crop varieties, we advocate: (i) concerted efforts in the advancement of 'omics' technologies, such as metabolomics, and (ii) an effort to redress the use of the technology in the regulatory assessment for metabolically engineered biotech crops.
Highlights
It is not facile to forensically detect gene-editing events at the molecular level, as no foreign DNA exists in the elite line
With the emergence of new edited crop varieties, we advocate: (i) concerted efforts in the advancement of ‘omics’ technologies, such as metabolomics, and (ii) an effort to redress the use of the technology in the regulatory assessment for metabolically engineered biotech crops
The last decade has been characterized by the adoption of genome-editing systems following the revolutionary discovery of transcriptional activator-like effector (TALE) proteins, which are more suitable for the precise engineering of targeted DNA sequences (Stella and Montoya, 2016) and the subsequent widespread adoption of the clustered regularly interspaced short palindromic repeats (CRISPR)-associated protein (Cas) system (Puchta and Fauser, 2014; Scheben et al, 2017; Yin et al, 2017)
Summary
The last decade has been characterized by the adoption of genome-editing systems following the revolutionary discovery of transcriptional activator-like effector (TALE) proteins, which are more suitable for the precise engineering of targeted DNA sequences (Stella and Montoya, 2016) and the subsequent widespread adoption of the clustered regularly interspaced short palindromic repeats (CRISPR)-associated protein (Cas) system (Puchta and Fauser, 2014; Scheben et al, 2017; Yin et al, 2017). Gene-editing techniques are currently revolutionizing biology, allowing far greater precision than previous mutagenic and transgenic approaches.
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