Abstract
Recent advances in programmable nucleases including meganucleases (MNs), zinc finger nucleases (ZFNs), transcription activator-like effector nucleases (TALENs), and clustered regularly interspaced short palindromic repeats-Cas (CRISPR-Cas) have propelled genome editing from explorative research to clinical and industrial settings. Each technology, however, features distinct modes of action that unevenly impact their applicability across the entire genome and are often tested under significantly different conditions. While CRISPR-Cas is currently leading the field due to its versatility, quick adoption, and high degree of support, it is not without limitations. Currently, no technology can be regarded as ideal or even applicable to every case as the context dictates the best approach for genetic modification within a target organism. In this review, we implement a four-pillar framework (context, feasibility, efficiency, and safety) to assess the main genome editing platforms, as a basis for rational decision-making by an expanding base of users, regulators, and consumers. Beyond carefully considering their specific use case with the assessment framework proposed here, we urge stakeholders interested in genome editing to independently validate the parameters of their chosen platform prior to commitment. Furthermore, safety across all applications, particularly in clinical settings, is a paramount consideration and comprehensive off-target detection strategies should be incorporated within workflows to address this. Often neglected aspects such as immunogenicity and the inadvertent selection of mutants deficient for DNA repair pathways must also be considered.
Highlights
The previous decade has seen a dramatic surge in the adoption and use of genome editing technologies, from academic research to industrial and clinical applications
We examine the four main genome editing technologies based on four pillars: context, feasibility, efficiency, and safety
The development of a new zinc finger nucleases (ZFNs) variant to target a particular DNA sequence is The development of a new ZFN variant to target a particular DNA sequence is generally regarded as laborious, time-consuming, and contingent on expertise in protein generally regarded as laborious, time-consuming, and contingent on expertise in protein engineering, context-dependent assembly, and enhancement techniques [7,31]
Summary
The previous decade has seen a dramatic surge in the adoption and use of genome editing technologies, from academic research to industrial and clinical applications This interest has been driven by the development of increasingly versatile and easy-to-use technologies, along with more robust detection methodologies to survey editing activity, both on- and off-target. Being deleterious to cells unless corrected, DSBs elicit nonhomologous end joining (NHEJ) and homology-directed repair (HDR) responses to mend the breaks [1,2] It is these repair mechanisms that underlie the ability to modify or “edit” the desired sequence. These diverging mechanisms result in different efficiency and precision: NHEJ frequently introduces sequence errors in the form of nucleotide insertions and deletions (indels) [4], whereas HDR uses a donor sequence with high similarity and overlap to the original sequence to produce precise, but low-efficiency repairs [2]
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